CN215611900U - Sugar melting tank - Google Patents

Abstract

The application relates to a sugar melting tank, which comprises a sugar melting tank body, a stirring component arranged on the sugar melting tank body, a crushing mechanism and a fixed cylinder, wherein the fixed cylinder is fixedly communicated with the top end of the sugar melting tank body, the crushing mechanism comprises a first crushing component, the first crushing component comprises a first rotating shaft which is arranged on the side wall of the fixed cylinder in a penetrating way and is rotationally connected with the fixed cylinder, with the coaxial fixed connection's of first axis of rotation first gear, wear to locate the solid fixed cylinder lateral wall and rather than the second axis of rotation of rotating being connected, second gear with the coaxial fixed connection of second axis of rotation, first gear and second gear engagement, first axis of rotation and second axis of rotation are parallel, first axis of rotation periphery has set firmly a plurality of first broken teeth, second axis of rotation periphery has set firmly a plurality of broken teeth of second, first broken tooth distributes with the broken tooth of second is crisscross each other, the first gear is kept away from the first gear reduction motor of one end fixedly connected with of first axis of rotation. The sugar melting tank of this application has thereby can broken cubic sugar and accelerate the advantage that cubic sugar melts.

Description

Sugar melting tank

Technical Field

The application relates to the field of sugar melting devices, in particular to a sugar melting tank.

Background

The sugar melting tank is a device for heating and melting sugar, and a pot body consists of a cylindrical stainless steel inner cylinder end socket and a heat transfer interlayer is formed. The outside is polished and packaged by stainless steel, and the surface is beautiful and elegant. The sugar melting tank body comprises a heating component and a heat preservation component and is used for providing heat for the materials to be heated and melted. The top end of the sugar melting tank body is provided with a feeding hole, and the bottom end of the sugar melting tank body is provided with a discharging hole. The sugar melting tank body is usually provided with a temperature measuring component, a pressure measuring component and the like and used for detecting the internal environment of the sugar melting tank body in the melting process of the powdery sugar. When melting the powdery sugar, adding the powdery sugar into the sugar melting tank body from the feed inlet, and then melting the powdery sugar through the heating assembly. However, the applicant has found that powdered sugar is liable to cake by absorbing water and form a lump of sugar, which melts slowly when it is charged into the body of the sugar-melting tank due to uneven heating.

SUMMERY OF THE UTILITY MODEL

In order to break up cubic sugar, accelerate its speed of melting, this application provides a sugar melting tank, adopts following technical scheme:

a sugar melting tank, which comprises a sugar melting tank body, a stirring component arranged on the sugar melting tank body, a crushing mechanism and a fixed cylinder, the fixed cylinder is fixedly communicated with the top end of the sugar melting tank body, the crushing mechanism comprises a first crushing component, the first crushing component comprises a first rotating shaft which is arranged on the side wall of the fixed cylinder in a penetrating way and is connected with the fixed cylinder in a rotating way, a first gear which is coaxially and fixedly connected with the first rotating shaft, a second rotating shaft which is arranged on the side wall of the fixed cylinder in a penetrating way and is connected with the fixed cylinder in a rotating way, and a second gear which is coaxially and fixedly connected with the second rotating shaft, the first gear is meshed with the second gear, the first rotating shaft is parallel to the second rotating shaft, a plurality of first crushing teeth are fixedly arranged on the periphery of the first rotating shaft, the periphery of the second rotating shaft is fixedly provided with a plurality of second crushing teeth, the first crushing teeth and the second crushing teeth are distributed in a staggered mode, and one end, far away from the first rotating shaft, of the first gear is fixedly connected with a first speed reduction motor.

Through adopting above-mentioned technical scheme, first broken subassembly can be broken to cubic sugar for this is internal to reentrant sugar melting tank after becoming likepowder sugar of cubic sugar, then melts under heating, stirring condition, sets up the speed that melts that first broken subassembly can accelerate cubic sugar.

Optionally, the crushing mechanism further comprises a second crushing assembly disposed below the first crushing assembly, the second crushing assembly comprises a third rotating shaft, a fourth rotating shaft, a fifth rotating shaft, a sixth rotating shaft, a third gear coaxially and fixedly connected with the third rotating shaft, a fourth gear coaxially and fixedly connected with the fourth rotating shaft and meshed with the third gear, a fifth gear coaxially and fixedly connected with the fifth rotating shaft and meshed with the fourth gear, and a sixth gear coaxially and fixedly connected with the sixth rotating shaft and meshed with the fifth gear, the third rotating shaft, the fourth rotating shaft, the fifth rotating shaft and the sixth rotating shaft are parallel, a plurality of third crushing teeth are fixedly disposed on the periphery of the third rotating shaft, a plurality of fourth crushing teeth are fixedly disposed on the periphery of the fourth rotating shaft, a plurality of fifth crushing teeth are fixedly disposed on the periphery of the fifth rotating shaft, and a plurality of sixth crushing teeth are fixedly arranged on the periphery of the sixth rotating shaft, and a linkage assembly is arranged between the third gear and the first gear.

Through adopting above-mentioned technical scheme, the broken piece sugar of back to first broken subassembly can further be broken to the broken second, makes the particle diameter of piece sugar further reduce to make the melting rate of piece sugar further accelerate.

Optionally, the linkage assembly comprises a first linkage rod fixedly connected with the first rotating shaft, a first belt pulley fixedly connected with one end of the first linkage rod away from the first rotating shaft, a second linkage rod fixedly connected with the fourth rotating shaft, a second belt pulley fixedly connected with one end of the second linkage rod away from the fourth rotating shaft, and a belt sleeved on the peripheries of the first belt pulley and the second belt pulley, wherein the second belt pulley is fixedly connected with the second linkage rod, and the first belt pulley is fixedly connected with one end of the first reduction motor fixedly connected with the first belt pulley away from the first linkage rod.

Through adopting above-mentioned technical scheme, the linkage subassembly makes under first gear motor's drive, and first broken subassembly, the broken subassembly of second can function simultaneously, the operation of being convenient for.

Optionally, broken mechanism is still including setting up in the first filtering component of the broken subassembly below of second, first filtering component is including wearing to locate the filter plate in the solid fixed cylinder, a plurality of trompils are seted up to the filter plate diapire, the baffle has upwards set firmly perpendicularly to one end wherein of filter plate, the baffle is located outside the solid fixed cylinder, the solid fixed cylinder is seted up in baffle department and is taken out the hole with baffle looks adaptation, the one end that the filter plate bottom surface was kept away from to the baffle has set firmly the scraping wings, the scraping wings keeps away from its one end of connecting with the baffle and just inclines to the direction of keeping away from the baffle downwards.

Through adopting above-mentioned technical scheme, make cubic sugar at first broken subassembly, the broken back of second broken subassembly through setting up first filter assembly, can filter the interception and not have broken abundant cubic sugar, and first filter assembly can dismantle for the cubic sugar that does not have broken abundant of filter plate interception can take out the refeed, and is broken once more.

Optionally, a first material baffle is vertically and upwards fixedly arranged at one end, far away from the baffle, of the filter plate.

Through adopting above-mentioned technical scheme, when outwards taking first filtering component out, first striker plate can reduce the dropping of cubic sugar from the filter plate.

Optionally, both ends of the filter plate close to the baffle plate are vertically and upwards fixedly provided with a second baffle plate.

Through adopting above-mentioned technical scheme, set up the second fender board and can further reduce taking out dropping of cubic sugar on the filter plate behind the first filtering component.

Optionally, demountable installation has the first material subassembly of trembling on the baffle, the first material subassembly of trembling includes fixed connection in the fixed cylinder lateral wall and is located the backup pad of baffle below, demountable installation in the baffle keep away from the connecting rod of the side of fixed cylinder, keep away from the one end of baffle with the connecting rod can dismantle the removal pipe of being connected, wear to locate in the removal pipe and rather than threaded connection's screw rod, the screw rod sets up along filter plate moving direction, the removal pipe removes along filter plate moving direction under the drive of screw rod, screw rod one end fixedly connected with second gear motor, removal pipe all are located the below of filter plate bottom surface.

Through adopting above-mentioned technical scheme, along with the great cubic sugar of particle diameter that filters out on the first filter component filter plate increases, can hinder likepowder sugar after the breakage to melt this internal drop of sugar jar, first shake material subassembly and can make first filter component rock, help likepowder sugar to melt this internal drop of sugar jar.

Optionally, a second filter assembly is arranged below the first filter assembly, and the second filter assembly has the same structure as the first filter assembly.

Through adopting above-mentioned technical scheme, set up direction reciprocating motion when first filtering component along the screw rod, perhaps when taking first filtering component out, the second filtering component can filter cubic sugar, reduces cubic sugar and directly drops to melting sugar jar is originally internal, and the second filtering component is the same with first filtering component structure, is convenient for melt sugar jar's manufacturing.

Optionally, a second shaking component is detachably mounted on the second filtering component. The second material shaking component has the same structure as the first material shaking component.

Through adopting above-mentioned technical scheme, the second is shaken the material subassembly and is rocked second filter assembly, helps likepowder sugar to melt this internal dropping of sugar jar, and the second is shaken the material subassembly and is shaken the material subassembly with first, is convenient for melt the manufacturing of sugar jar.

In summary, the present application includes at least one of the following beneficial technical effects:

1. by arranging the crushing mechanism, when the lump sugar is melted, the particle size of the lump sugar can be reduced under the action of the first crushing assembly, and the melting rate of the lump sugar is improved;

2. the second filtering component is arranged to further break the blocky sugar, so that the particle size of the blocky sugar is further reduced, and the melting of the sugar is further accelerated;

3. through setting up first filtering component, first shaking the material subassembly, can intercept the great sugar of particle diameter, feed again, first shaking the material subassembly simultaneously and can rocking first filtering component, reduce the blocky sugar of interception and to the hindrance of likepowder sugar, the likepowder sugar of being convenient for drops to melt sugar jar originally internally.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a partial sectional view for showing the stirring component, the first filtering component, the first material shaking component, the second filtering component and the second material shaking component.

Fig. 3 is an enlarged view of a portion a in fig. 2.

Fig. 4 is a partial sectional view for illustrating the first crushing assembly.

Fig. 5 is a partial sectional view of the linkage assembly to show the second crushing assembly.

Description of reference numerals: 1. a sugar melting tank body; 2. a stirring assembly; 21. a stirring shaft; 22. a third reduction motor; 23. a first stirring rod; 24. a second stirring rod; 25. fixing the rod; 26. a sugar scraping plate; 261. a fixing plate; 262. a squeegee; 3. a fixed cylinder; 31. drawing the hole; 32. a groove; 4. a feeding cylinder; 5. a crushing mechanism; 51. a first crushing assembly; 511. a first rotating shaft; 5111. a first crushing tooth; 512. a second rotating shaft; 5121. a second crushing tooth; 513. a first gear; 514. a second gear; 515. a first material stopping plate; 516. a second material stopping plate; 52. a second crushing assembly; 521. a third rotating shaft; 5211. a third crushing tooth; 522. a fourth rotating shaft; 5221. a fourth crushing tooth; 523. a fifth rotating shaft; 5231. a fifth crushing tooth; 524. a sixth rotating shaft; 5241. a sixth crushing tooth; 525. a third gear; 526. a fourth gear; 527. a fifth gear; 528. a sixth gear; 53. a linkage assembly; 531. a first linkage rod; 532. a second linkage rod; 533. a first pulley; 534. a second pulley; 535. a belt; 536. a first reduction motor; 54. a first filter assembly; 541. filtering the plate; 542. a baffle plate; 5421. a handle; 543. a first striker plate; 544. a second retainer plate; 545. a material sliding plate; 55. a first shaking assembly; 551. a support plate; 552. a connecting rod; 553. moving the tube; 5531. a guide bar; 554. a first connecting plate; 555. a first bolt; 556. a screw; 557. a second connecting plate; 558. a second bolt; 559. a second reduction motor; 56. a second filter assembly; 57. and the second material shaking component.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses a sugar melting tank. Referring to fig. 1, the sugar melting tank includes a sugar melting tank body 1, a stirring assembly 2 installed on the sugar melting tank body 1, a fixed cylinder 3 fixedly communicated with the sugar melting tank body 1, a feeding cylinder 4 installed at one end of the fixed cylinder 3 far away from the sugar melting tank body 1, and a crushing mechanism 5 installed at the fixed cylinder 3.

Referring to fig. 1 and 2, the sugar melting tank body 1 is a tank, the stirring component 2 is located in the sugar melting tank body 1, the stirring component 2 comprises a stirring shaft 21, the stirring shaft 21 penetrates through the bottom wall of the sugar melting tank body 1 and is connected with the bottom wall of the sugar melting tank body in a rotating manner, and the stirring shaft 21 extends out of a third speed reduction motor 22 fixedly connected with one end of the bottom wall of the sugar melting tank body 1. One end of the stirring shaft 21 far away from the third speed reducing motor 22 is symmetrically provided with two first stirring rods 23, the two first stirring rods 23 are positioned on the same plane, and one ends of the two first stirring rods 23 far away from the stirring shaft 21 incline towards the bottom wall of the sugar melting tank body 1. The stirring shaft 21 is symmetrically provided with two second stirring rods 24 at one end side surface close to the bottom wall of the sugar melting tank body 1 in the sugar melting tank body 1, and the second stirring rods 24 and the first stirring rods 23 are positioned in the same plane. Two second stirring rods 24 are arranged in parallel with the bottom wall of the sugar melting tank body 1. A fixing rod 25 is respectively arranged between the first stirring rod 23 and the second stirring rod 24, one end of the fixing rod 25 is fixedly connected with one end of the second stirring rod 24 far away from the stirring shaft 21, and the other end of the fixing rod 25 is fixedly connected with one end of the first stirring rod 23 far away from the stirring shaft 21 and extends towards one end far away from the second stirring rod 24.

Referring to fig. 2, two sugar scraping plates 26 have evenly set firmly between dead lever 25 and the 1 medial surface of sugar melting tank body, and sugar scraping plates 26 is including setting firmly the fixed plate 261 in the dead lever 25 periphery, and fixed plate 261 is square board, and fixed plate 261 side has set firmly scraper 262, and scraper 262 is trapezoidal board, and scraper 262 keeps away from the lateral wall of dead lever 25 and closely contradicts with 1 medial surface of sugar melting tank body. Two sugar scraping plates 26 are also respectively and evenly fixed on the two second stirring rods 24 along the length direction thereof. The sugar scraping plate 26 is positioned in the same plane with the first stirring rod 23, the second stirring rod 24 and the fixing rod 25.

Referring to fig. 1, the fixed cylinder 3 is a square cylinder, and the fixed cylinder 3 is located above the sugar melting pot body 1. The feeding cylinder 4 is an inverted square-table cylinder, the feeding cylinder 4 is fixedly communicated with one end, away from the sugar melting tank body 1, of the fixed cylinder 3, and the opening area of one end, away from the fixed cylinder 3, of the feeding cylinder 4 is larger than the opening area of one end, close to the fixed cylinder 3.

Referring to fig. 1, the crushing mechanism 5 includes a first crushing assembly 51 mounted on the fixed cylinder 3, a second crushing assembly 52 mounted on the fixed cylinder 3 and located below the first crushing assembly 51, a linkage assembly 53 fixedly mounted between the first crushing assembly 51 and the second crushing assembly 52 and located outside the fixed cylinder 3, a first filtering assembly 54 detachably mounted on the fixed cylinder 3 and located below the second crushing assembly 52, a second filtering assembly 56 detachably mounted on the fixed cylinder 3 and located below the first filtering assembly 54, a first material shaking assembly 55 detachably mounted on the first filtering assembly 54, a second material shaking assembly 57 detachably mounted on the second filtering assembly 56, and the first material shaking assembly 55 are located outside the fixed cylinder 3.

Referring to fig. 4, the first crushing assembly 51 includes a first rotating shaft 511 and a second rotating shaft 512 which are parallel to each other and respectively penetrate through two symmetrical sidewalls of the fixed cylinder 3, the first rotating shaft 511 and the second rotating shaft 512 are respectively rotatably connected to the fixed cylinder 3, a first gear 513 is coaxially and fixedly connected to one end of the first rotating shaft 511, which extends out of the fixed cylinder 3, a second gear 514 is coaxially and fixedly connected to one end of the second rotating shaft 512, which extends out of the fixed cylinder 3, and the first gear 513 and the second gear 514 are engaged with each other. A plurality of first crushing teeth 5111 are uniformly and fixedly arranged on the periphery of the first rotating shaft 511, a plurality of second crushing teeth 5121 are uniformly and fixedly arranged on the periphery of the second rotating shaft 512, and the first crushing teeth 5111 and the second crushing teeth 5121 are convex plates. The first crushing teeth 5111 and the second crushing teeth 5121 are staggered with each other, a plurality of first material blocking plates 515 parallel to the first crushing teeth 5111 are uniformly and fixedly arranged between the first crushing teeth 5111 and the side wall of the fixed cylinder 3, the first material blocking plates 515 are trapezoidal plates, and the first material blocking plates 515 and the first crushing teeth 5111 are distributed in a staggered manner. A plurality of second material stopping plates 516 parallel to the second crushing teeth 5121 are uniformly and fixedly arranged between the second crushing teeth 5121 and the side wall of the fixed cylinder 3, the second material stopping plates 516 are trapezoidal plates, and the second material stopping plates 516 and the second crushing teeth 5121 are distributed in a staggered manner.

Referring to fig. 5, the second crushing assembly 52 includes a third rotating shaft 521, a fourth rotating shaft 522, a fifth rotating shaft 523 and a sixth rotating shaft 524 which are parallel to each other and respectively penetrate through two symmetrical sidewalls of the fixed cylinder 3, the third rotating shaft 521 is parallel to the second rotating shaft 512, and the third rotating shaft 521, the fourth rotating shaft 522, the fifth rotating shaft 523 and the sixth rotating shaft 524 are respectively rotatably connected to the fixed cylinder 3. The end of the third rotating shaft 521 extending out of the fixed cylinder 3 is coaxially and fixedly connected with a third gear 525, the end of the fourth rotating shaft 522 extending out of the fixed cylinder 3 is coaxially and fixedly connected with a fourth gear 526, the end of the fifth rotating shaft 523 extending out of the fixed cylinder 3 is coaxially and fixedly connected with a fifth gear 527, the end of the sixth rotating shaft 524 extending out of the fixed cylinder 3 is coaxially and fixedly connected with a sixth gear 528, the third gear 525 is meshed with the fourth gear 526, the fourth gear 526 is meshed with the fifth gear 527, the fifth gear 527 is meshed with the sixth gear 528, and the third gear 525, the fourth gear 526, the fifth gear 527, the sixth gear 528 is located outside the same side wall of the fixed cylinder 3 as the first gear 513 and the second gear 514. A plurality of third crushing teeth 5211 are uniformly and fixedly arranged on the periphery of the third rotating shaft 521, a plurality of fourth crushing teeth 5221 are uniformly and fixedly arranged on the periphery of the fourth rotating shaft 522, a plurality of fifth crushing teeth 5231 are uniformly and fixedly arranged on the periphery of the fifth rotating shaft 523, and a plurality of sixth crushing teeth 5241 are uniformly and fixedly arranged on the periphery of the sixth rotating shaft 524. Third crushing tooth 5211, fourth crushing tooth 5221, fifth crushing tooth 5231, and sixth crushing tooth 5241 are all annular plates. Third crushing tooth 5211 and fourth crushing tooth 5221, fourth crushing tooth 5221 and fifth crushing tooth 5231, and fifth crushing tooth 5231 and sixth crushing tooth 5241 are staggered.

Referring to fig. 4 and 5, the linkage assembly 53 is disposed between the first gear 513 and the third gear 525, the linkage assembly 53 includes a first linkage rod 531 coaxially and fixedly connected to one end of the first gear 513 away from the first rotation axis 511, and a second linkage rod 532 coaxially and fixedly connected to one end of the third gear 525 away from the third rotation axis 521, one end of the first linkage rod 531 away from the first rotation axis 511 is fixedly connected to a first belt pulley 533, one end of the second linkage rod 532 away from the fourth rotation axis 522 is fixedly connected to a second belt pulley 534, a belt 535 is sleeved on the first belt pulley 533 and the second belt pulley 534, one end of the first belt pulley 533 away from the first linkage rod 531 is fixedly connected to a first reduction motor 536, and the first reduction motor 536 is fixedly disposed on the outer side wall of the fixed cylinder 3.

Referring to fig. 2, the first filter assembly 54 includes a filter plate 541 disposed through the fixed cylinder 3, the filter plate 541 is a square plate adapted to the fixed cylinder 3, and a plurality of openings are uniformly formed on the filter plate 541. One end of the filter plate 541 is vertically and upwardly provided with a baffle plate 542, and the baffle plate 542 is a square plate. The side wall of the fixed cylinder 3 is provided with a drawing hole 31 matched with the baffle 542 at the baffle 542, and the baffle 542 covers the drawing hole 31. Two handles 5421 are fixedly arranged on the side of the baffle plate 542 far away from the fixed cylinder 3. One end of the filter plate 541 far from the baffle 542 is vertically and upwardly fixedly provided with a first material blocking plate 543, and the first material blocking plate 543 is a square plate with the same height as the drawing hole 31. The other two ends of the filter plate 541 are vertically and upwardly fixed with a second baffle plate 544, the second baffle plate 544 is a square plate with the same height as the drawing hole 31, and the side surface of the second baffle plate 544 is tightly abutted against the inner side surface of the fixed cylinder 3. One end of the second material blocking plate 544 is fixedly connected to the side surface of the first material blocking plate 543, and the other end is fixedly connected to the side surface of the blocking plate 542. The fixed cylinder 3 is provided with grooves 32 respectively formed on the side walls of the first material blocking plate 543 and the second material blocking plate 544, the first material blocking plate 543 and the second material blocking plate 544 are respectively located in the grooves 32, and the filter plate 541 can reciprocate along the length direction of the second material blocking plate 544. The top end of the side surface of the baffle plate 542 close to the first material blocking plate 543 is fixedly connected with a material sliding plate 545, the material sliding plate 545 is a square plate, one end of the material sliding plate 545 far away from the connection with the baffle plate 542 is fixedly connected to the top surface of the filter plate 541, and one end of the material sliding plate 545 near the filter plate 541 inclines towards the direction far away from the baffle plate 542. Two side surfaces of the material sliding plate 545 respectively and tightly abut against two opposite side surfaces of the second material baffle 544.

Referring to fig. 2 and 3, the first material shaking assembly 55 is detachably mounted on the side of the blocking plate 542 far away from the first material blocking plate 543. The first shaking assembly 55 comprises a support plate 551 fixedly arranged below the bottom end of the fixed cylinder 3 of the baffle 542, a connecting rod 552 detachably arranged at the baffle 542, and a moving pipe 553 detachably connected with the connecting rod 552. Connecting rod 552 is L shape, and connecting rod 552 one end fixedly connected with first connecting plate 554, and first connecting plate 554 is worn to be equipped with two first bolts 555, through first bolt 555 with connecting rod 552 demountable installation on baffle 542. One end of the connecting rod 552 far from the baffle 542 is fixedly connected with a second connecting plate 557, a second bolt 558 is arranged on the second connecting plate 557 in a penetrating manner, the connecting rod 552 is detachably mounted on the outer side wall of the moving pipe 553 through the second bolt 558, and the moving pipe 553 is located below the connecting rod 552. A screw 556 is threaded into the moving pipe 553, and the screw 556 moves along the filter 541. One end of the screw 556, which is far away from the baffle 542, is fixedly connected with a second speed reduction motor 559, and the second speed reduction motor 559 is fixedly arranged on the top surface of the supporting plate 551. A guide rod 5531 connected with the moving pipe 553 in a sliding way is arranged below the screw 556 in a penetrating way, the guide rod 5531 is parallel to the screw 556, and one end of the guide rod 5531 far away from the second speed reducing motor 559 is fixedly arranged on the side wall of the fixed cylinder 3. The second reduction motor 559, the screw 556, and the moving pipe 553 are located above the support plate 551 and below the bottom surface of the filter sheet 541.

Referring to fig. 2 and 3, the second filter assembly 56 has the same structure as the first filter assembly 54, and the second material shaking assembly 57 has the same structure as the first material shaking assembly 55.

The implementation principle of the sugar melting tank in the embodiment of the application is as follows: when the sugar to be melted is in a block shape, the sugar is fed from the feeding cylinder 4, the block-shaped sugar is crushed into sugar with smaller particles by the first crushing assembly 51 and then enters the second crushing assembly 52, and the sugar which is changed into powder-shaped sugar directly passes through the first filtering assembly 54 and the second filtering assembly 56 and reaches the sugar melting tank body 1. Part of the sugar cake that is not broken reaches the filter plate 541, and the increase of the sugar cake on the filter plate 541 hinders the powdery sugar from falling into the tank. The first shaking component 55 drives the baffle 542 and the filter plate 541 to move back and forth, so that the sugar on the filter plate 541 shakes back and forth, and the powdered sugar falls into the sugar melting tank body 1. And because the material sliding plate 545 is arranged, the area of the sugar falling on the filter plate 541 is limited, so that the sugar on the filter plate 541 cannot fall on the ground when the first filter assembly 54 is driven by the first material shaking assembly 55 to move back and forth. When the first filtering component 54 is driven by the first shaking component 55 to move back and forth, part of the sugar drops onto the second filtering component 56, and the second filtering component 56 blocks the sugar and prevents the sugar from dropping into the sugar melting tank body 1. When the filter plates 541 of the first filter module 54 are filled with lump sugar, the first shaking module 55 is detached from the baffle plate 542, the connecting rod 552 is detached from the moving pipe 553, the first filter module 54 is pulled out, and the lump sugar is fed again from the feed cylinder 4. The first filter assembly 54 is then replaced while the first shaking assembly 55 is installed. Similarly, when the second filter module 56 is filled with the candy bars, the second filter module 56 is removed and the candy bars are re-fed from the feed cylinder 4. Second filter assembly 56 is then reinstalled in place. Can carry out the breakage to cubic sugar through setting up crushing mechanism 5, then become in likepowder sugar reentrant sugar melting tank body 1, can improve the rate of melting of cubic sugar.

After the feeding is finished, the blocky sugar is changed into powdery sugar to enter the sugar melting tank body 1, and then the sugar is heated and stirred. The stirring component 2 can accelerate the melting of sugar, and the sugar scraping plate 26 can reduce the sugar attached to the inner side wall of the sugar melting tank body 1.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides a sugar melting tank, includes sugar melting tank body (1), installs stirring subassembly (2) on sugar melting tank body (1), its characterized in that: the sugar melting pot is characterized by further comprising a crushing mechanism (5) and a fixed barrel (3), wherein the fixed barrel (3) is fixedly communicated with the top end of the sugar melting pot body (1), the crushing mechanism (5) comprises a first crushing component (51), the first crushing component (51) comprises a first rotating shaft (511) which penetrates through the side wall of the fixed barrel (3) and is rotatably connected with the fixed barrel, a first gear (513) which is coaxially and fixedly connected with the first rotating shaft (511), a second rotating shaft (512) which penetrates through the side wall of the fixed barrel (3) and is rotatably connected with the fixed barrel, and a second gear (514) which is coaxially and fixedly connected with the second rotating shaft (512), the first gear (513) is meshed with the second gear (514), the first rotating shaft (511) is parallel to the second rotating shaft (512), a plurality of first crushing teeth (5111) are fixedly arranged on the periphery of the first rotating shaft (511), and a plurality of second crushing teeth (5121) are fixedly arranged on the periphery of the second rotating shaft (512), the first crushing teeth (5111) and the second crushing teeth (5121) are distributed in a staggered mode, and one end, far away from the first rotating shaft (511), of the first gear (513) is fixedly connected with a first speed reduction motor (536).

2. A sugar-melting tank as claimed in claim 1, wherein: the crushing mechanism (5) further comprises a second crushing component (52) arranged below the first crushing component (51), the second crushing component (52) comprises a third rotating shaft (521), a fourth rotating shaft (522), a fifth rotating shaft (523), a sixth rotating shaft (524), a third gear (525) coaxially and fixedly connected with the third rotating shaft (521), a fourth gear (526) coaxially and fixedly connected with the fourth rotating shaft (522) and meshed with the third gear (525), a fifth gear (527) coaxially and fixedly connected with the fifth rotating shaft (523) and meshed with the fourth gear (526), and a sixth gear (528) coaxially and fixedly connected with the sixth rotating shaft (524) and meshed with the fifth gear (527), wherein the third rotating shaft (521), the fourth rotating shaft (522), the fifth rotating shaft (523), Sixth axis of rotation (524) are parallel, third axis of rotation (521) periphery sets firmly a plurality of broken teeth of third (5211), fourth axis of rotation (522) periphery sets firmly a plurality of broken teeth of fourth (5221), fifth axis of rotation (523) periphery sets firmly a plurality of broken teeth of fifth (5231), sixth axis of rotation (524) periphery sets firmly a plurality of broken teeth of sixth (5241), be provided with linkage assembly (53) between third gear (525) and first gear (513).

3. A sugar-melting tank as claimed in claim 2, wherein: linkage subassembly (53) include with first pivot axis (511) fixed connection's first gangbar (531), keep away from one end fixed connection's first belt pulley (533) of first pivot axis (511) with first gangbar (531), with the second gangbar (532) of the fixed connection of fourth pivot axis (522), keep away from one end fixed connection's second belt pulley (534) of fourth pivot axis (522) with second gangbar (532), the outlying belt (535) of first belt pulley (533) and second belt pulley (534) are located to the cover, first gear motor (536) fixed connection is in the one end that first gangbar (531) was kept away from in first belt pulley (533).

4. A sugar-melting tank as claimed in claim 2, wherein: broken mechanism (5) are still including setting up in first filtering component (54) of the broken subassembly (52) below of second, first filtering component (54) are including wearing to locate filter plate (541) in solid fixed cylinder (3), a plurality of trompils are seted up to filter plate (541) diapire, baffle (542) have upwards been set firmly perpendicularly to one end wherein of filter plate (541), baffle (542) are located solid fixed cylinder (3) outward, gu fixed cylinder (3) locate in baffle (542) offer with draw hole (31) of baffle (542) looks adaptation, the one end that filter plate (541) bottom surface was kept away from in baffle (542) has set firmly sliding plate (545), sliding plate (545) keep away from its one end of connecting department with baffle (542) and downwards and to the direction slope of keeping away from baffle (542).

5. A sugar-melting tank as claimed in claim 4, wherein: one end of the filter plate (541) far away from the baffle (542) is vertically and upwards fixedly provided with a first material blocking plate (543).

6. A sugar-melting tank as claimed in claim 4, wherein: and both ends of the filter plate (541) close to the baffle (542) are vertically and upwards fixedly provided with second baffle plates (544).

7. A sugar-melting tank as claimed in claim 4, wherein: the baffle (542) is detachably provided with a first material shaking component (55), the first material shaking component (55) comprises a support plate (551) which is fixedly connected with the side wall of the fixed cylinder (3) and is positioned below the baffle (542), a connecting rod (552) which is detachably arranged on the side surface of the baffle (542) far away from the fixed cylinder (3), a moving pipe (553) which is detachably connected with one end of the connecting rod (552) far away from the baffle (542), and a screw rod (556) which is arranged in the moving pipe (553) in a penetrating way and is in threaded connection with the moving pipe, the screw (556) is arranged along the moving direction of the filter plate (541), the moving pipe (553) is driven by the screw (556) to move along the moving direction of the filter plate (541), one end of the screw rod (556) is fixedly connected with a second speed reducing motor (559), and the second speed reducing motor (559) and the moving pipe (553) are both positioned below the bottom surface of the filter plate (541).

8. The sugar-melting tank as claimed in claim 7, wherein: a second filtering component (56) is arranged below the first filtering component (54), and the structure of the second filtering component (56) is the same as that of the first filtering component (54).

9. A sugar-melting tank as claimed in claim 8, wherein: a second material shaking component (57) is detachably mounted on the second filtering component (56), and the second material shaking component (57) and the first material shaking component (55) are identical in structure.

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