CN114234554B

CN114234554B - A quick cooling device for jelly production

Info

Publication number: CN114234554B
Application number: CN202111587542.XA
Authority: CN
Inventors: 胡志; 庞凯平; 邓声安; 苏珍
Original assignee: Hunan Xinzhongyi Food Co ltd
Current assignee: Hunan Xinzhongyi Food Co ltd
Priority date: 2021-12-23
Filing date: 2021-12-23
Publication date: 2023-05-09
Anticipated expiration: 2041-12-23
Also published as: CN114234554A

Abstract

The utility model belongs to the technical field of jelly production, in particular to a rapid cooling device for jelly production, which comprises a box body; the automatic feeding device comprises a box body, and is characterized in that a feeding port and a discharging port are formed in the box body, a winding assembly is arranged in the middle of the top end of the box body, the output end of the winding assembly is connected with a lifting cylinder through a pull rope, a spray hole is formed in the side wall of the top end of the lifting cylinder, a motor is arranged in the lifting cylinder, the top end of the motor is connected with fan blades through a rotating rod, a fixing ring is connected to the inner wall of the box body, and a woven net is connected between the fixing ring and the side wall of the top end of the lifting cylinder; according to the utility model, the cooling water in the box body can continuously circulate in the vertical direction under the action of the lifting cylinder, so that the heat exchange between the cooling water and the jelly is promoted, and the damage of the jelly in the cooling process can be reduced.

Description

A quick cooling device for jelly production

Technical Field

The utility model belongs to the technical field of jelly production, and particularly relates to a rapid cooling device for jelly production.

Background

The jelly food is an industry which rapidly develops in recent years, the shaping of the jelly is mainly formed by a cooling method, after the jelly is packaged, the jelly is generally cooled by being put into cold water of a cooling water tank, after the cooling is finished, the jelly is fished out manually, and then the next batch of jelly is cooled; the manual salvage is not only labor-intensive, but also is not easy to salvage the jelly in the cooling water tank completely.

One chinese patent with publication number CN210425688U discloses a jelly cooling device, a guide ring is fixed on the top of the cooling water tank; the lifting shaft sequentially passes through the inner top wall of the cooling water tank and the guide ring from bottom to top and is fixedly connected with the output end of the unreeling machine; a feed inlet is arranged at the top of the cooling water tank; a fixing ring is fixed in the inner cavity of the cooling water tank; the outer ring of the fixed ring is matched with the inner cavity of the cooling water tank; the baffle ring is sleeved outside the shaft body of the lifting shaft; the bottom end of the lifting shaft is provided with a lower baffle ring; a plurality of discharging holes are uniformly distributed on the outer side wall of the cooling water tank; the discharging holes are circumferentially distributed on the cooling water tank; the bottom of the discharging hole and the top of the fixing ring are arranged on the same horizontal plane. When the utility model is used, the structure can automatically salvage the jelly, and the salvage efficiency of the jelly is improved by automatically salvaging the jelly at one time and reducing the labor intensity.

However, when the jelly cooling device in the above technology cools the jelly, the heat exchange efficiency between the jelly and the surrounding water is low because the jelly in the cooling water tank is relatively static, and although the heat exchange between the jelly and the cooling water can be promoted by stirring the jelly through the stirring equipment, the stirring equipment is easy to damage the formed jelly, and the processing quality of the jelly is affected.

Accordingly, the present utility model provides a rapid cooling device for jelly production.

Disclosure of Invention

In order to overcome the deficiencies of the prior art, at least one technical problem presented in the background art is solved.

The technical scheme adopted for solving the technical problems is as follows: the utility model relates to a rapid cooling device for jelly production, which comprises a box body; the novel lifting box comprises a box body, and is characterized in that a feeding hole is formed in the top end of the box body, a group of evenly distributed discharging holes are formed in the middle of the side wall of the box body, a winding assembly is arranged in the middle of the top end of the box body, a pull rope is wound at the output end of the winding assembly, the other end of the pull rope stretches into the box body and is connected with a lifting cylinder, an opening is formed in the bottom end of the lifting cylinder, a spray hole is formed in the side wall of the top end of the lifting cylinder, a motor is arranged in the lifting cylinder, the top end of the motor is connected with fan blades through a rotating rod, a fixed ring is connected to the inner wall of the box body corresponding to the bottom end of the discharging hole, a woven net is connected between the fixed ring and the side wall of the top end of the lifting cylinder, and a limiting screen plate matched with the lifting cylinder is connected in the middle of the bottom surface of the box body; when the jelly cooling device in the prior art cools the jelly, the jelly in the cooling water tank is relatively static, so that the heat exchange efficiency of the jelly and surrounding water is lower, and although the heat exchange of the jelly and the cooling water can be promoted by stirring of the stirring equipment, the stirring equipment is easy to damage the formed jelly, and the processing quality of the jelly is influenced; when the jelly is required to be cooled, the winding component releases the pull rope, so that the lifting cylinder at the bottom of the jelly falls into the limiting screen plate and is limited, the woven mesh between the lifting cylinder and the fixed ring is in a funnel shape with the upper part wide and the lower part narrow, then the jelly is put into the box body containing cooling water from the feed port, and meanwhile, the fan blades are driven by the motor to rotate, so that the cooling water at the bottom of the lifting cylinder can be continuously sucked by the fan blades and is upwards conveyed to the spray hole to be sprayed out, the cooling water in the box body can continuously circulate in the vertical direction under the action of the lifting cylinder, thereby promoting the heat exchange of the cooling water and the jelly, reducing the damage of the jelly in the cooling process.

Preferably, the injection direction of the injection hole is inclined downwards; when the woven mesh is discharged under the drive of the lifting cylinder, the fan blades which continue to rotate pump air at the bottom end of the lifting cylinder to the spray holes to spray, and the air flow direction sprayed by the spray holes is consistent with the inclined plane of the woven mesh at the moment, so that the jelly fished up on the woven mesh can be blown off by utilizing the air flow sprayed by the spray holes, the collection of the jelly is promoted, meanwhile, the air flow at the spray holes can promote the cooling and drying of the jelly, and water drops on the woven mesh can be blown off, the residue of cooling water on the surface of the jelly is reduced, and the processing quality of the jelly is improved.

Preferably, a limiting piece is connected to the inner wall of the lifting cylinder corresponding to one side of the rotating rod, and an impact block matched with the limiting piece is connected to the side wall of the rotating rod on one side of the limiting piece through a traction rope; when the lifting cylinder is lifted from the cooling water surface, the impact block can continuously impact the limiting piece under the drive of the rotating rod, so that the surface of the lifting cylinder and the woven mesh are vibrated, the sliding collection of jelly on the woven mesh is promoted, and meanwhile, the throwing-off of the jelly and water drops on the woven mesh is also promoted.

Preferably, the limiting piece is provided with an adsorption block, an electromagnet which can attract the adsorption block is connected to the outer wall of the lifting cylinder corresponding to the top end of the limiting piece, a supporting frame is connected to the inner wall of the lifting cylinder at the bottom end of the limiting piece, and the limiting piece is connected with the bracket through a spring and can freely slide in the lifting cylinder; when the lifting cylinder bottom stretches into the cooling liquid, a gap exists between the limiting piece and the rotating impact block under the tensile force of the spring, the resistance generated by rotation of the limiting piece to the rotating rod is reduced, meanwhile, when the lifting cylinder stretches out of the cooling liquid and needs to drive the woven mesh to shake, the electromagnet works and drives the limiting piece to move to one side close to the impact block through the attraction adsorption block, and accordingly the rotating rod can drive the woven mesh to shake smoothly through the impact block when rotating.

Preferably, the limiting piece is made of elastic membrane materials, an elastic body is connected between the limiting piece and the inner wall of the lifting cylinder, a racket rod is rotatably connected to the outer wall of the lifting cylinder on one side of the limiting piece, a telescopic bag is connected between the bottom end of the racket rod and the outer wall of the lifting cylinder on one side, and an air passage which is communicated with the telescopic bag and an inner cavity of the limiting piece is formed in the side wall of the lifting cylinder; when not needing the impact piece to collide with the locating part, the locating part of elastic membrane material warp to the one side of keeping away from the impact piece this moment under the effect of spring, when needs drive the mesh grid through the rotation of bull stick shake, the electro-magnet can be through the attraction to the adsorption block this moment for the locating part resets to the position department that collides mutually with the impact piece, when the impact piece extrudees the locating part simultaneously, its inside gas flows into the flexible bag through the air flue, make the flexible bag drive the rapping bar and rotate after the extension, the rapping bar can play the effect of beating the mesh grid at subsequent reset process, further promote the shake effect of mesh grid.

Preferably, a push rod is arranged on the inner wall of the lifting cylinder at the top end of the discharge hole, the bottom end of the push rod is connected with an annular plate capable of plugging the discharge hole, the bottom end of the feed inlet is connected with an arc-shaped material guiding cavity, and the bottom end of the material guiding cavity extends to the middle of the box body; before the jelly gets into inside box, the push rod control annular plate carries out the shutoff to the discharge gate, drives the middle part of mesh grid through the lift cylinder simultaneously and upwards jack-up, and the jelly that flows in from the feed inlet can follow the stable flow of direction chamber at the middle part top of mesh grid this moment to constantly flow down along the inclined plane of mesh grid, reduce the jelly and directly throw into in the box from the feed inlet, lead to the jelly to drop from higher position and take place the condition of damage.

Preferably, a diversion hole communicated with the lifting cylinder is formed in the inner wall of the lifting cylinder at one side of the spray hole, the spray direction of the diversion hole is inclined upwards, and control valves are respectively arranged in the spray hole and the diversion hole; when the woven mesh is lowered into cooling water to cool the jelly, the control valve in the time division flow hole is opened, and the control valve in the spray hole is closed, so that water flow sprayed upwards obliquely from the inside of the lifting cylinder can spray the jelly on one side upwards, and meanwhile, the jelly can slide to the position of the time division flow hole along the inclined surface of the woven mesh, so that the jelly can move in the cooling water continuously, and the cooling efficiency of the jelly is further improved.

Preferably, the bottom of the woven mesh is connected with a group of mutually communicated flexible pipes, one side of each flexible pipe facing the woven mesh is provided with a plurality of air holes, the flexible pipes are connected with the air outlet end of an external air pump through an air pipe, and the air inlet end of the air pump is communicated with a cold air source; the air pump can convey the cold air at the cold air source into the flexible pipe, and the cold air is sprayed at the woven mesh through the air holes on the surface of the flexible pipe, so that jelly at the woven mesh can be directly cooled, meanwhile, the movement of the jelly in cooling water can be promoted, and the cooling efficiency of the jelly is further improved.

Preferably, a group of concave parts are arranged on the flexible pipe, the width of each concave part is gradually increased from inside to outside, and the positions of the woven mesh corresponding to the concave parts are attached to the concave parts; the jelly can flow into the woven mesh at the concave part, and the concave part arranged at the moment can increase the air injection area of the flexible pipe to the jelly, so that the jelly can be cooled more rapidly.

Preferably, a group of mutually attracted magnetic blocks are symmetrically connected to the side wall of the concave part; when the middle part of the woven mesh moves upwards gradually, the magnetic blocks attracted to each other are instantaneously separated along with the continuous stretching of the woven mesh and the flexible pipe, and drive the flexible pipe and the woven mesh to extend and shake, so that the discharge of jelly is further promoted, the residues of the jelly and the moisture on the woven mesh are reduced, and the processing quality of the jelly is improved.

The beneficial effects of the utility model are as follows:

1. according to the utility model, the cooling water in the box body continuously circulates in the vertical direction under the action of the lifting cylinder, so that the heat exchange between the cooling water and the jelly is promoted, the damage of the jelly in the cooling process is reduced, and after the jelly is cooled, the winding component pulls the lifting cylinder and the middle part of the woven mesh to move upwards through the pull rope, so that the woven mesh forms a funnel shape with narrow upper part and wide lower part, the jelly fished up by the woven mesh can flow out from the discharge port, and the cooled jelly is convenient to enter the next procedure.

2. According to the utility model, when the woven mesh is driven by the lifting cylinder to discharge, the fan blades which continue to rotate pump air at the bottom end of the lifting cylinder to the spray holes to spray, and the direction of the air flow sprayed by the spray holes is consistent with the inclined plane of the woven mesh, so that the jelly fished up on the woven mesh can be blown off by utilizing the air flow sprayed by the spray holes to promote the collection of the jelly, and meanwhile, the air flow at the spray holes can promote the cooling and drying of the jelly, and water drops on the woven mesh can be blown off, so that the residue of cooling water on the surface of the jelly is reduced, and the processing quality of the jelly is improved.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

The utility model is further described below with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic diagram of the structure of the present utility model;

FIG. 3 is an enlarged view at A in FIG. 2;

fig. 4 is a schematic structural view of the flexible tube and the mesh grid in the second embodiment;

in the figure: the device comprises a box body 1, a feed inlet 2, a discharge outlet 3, a winding component 4, a pull rope 5, a lifting cylinder 6, a spray hole 7, a motor 8, fan blades 9, a fixed ring 10, a woven mesh 11, a limiting screen plate 12, a limiting piece 13, an impact block 14, an adsorption block 15, an electromagnet 16, an elastomer 17, a racket rod 18, a telescopic bag 19, an air flue 20, a push rod 21, an annular plate 22, a guide cavity 23, a split hole 24, a control valve 25, a flexible pipe 26, a concave part 27 and a magnetic block 28.

Detailed Description

The utility model is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Embodiment one:

referring to fig. 1-3, a rapid cooling device for jelly production according to an embodiment of the present utility model includes a case 1; the novel automatic lifting box is characterized in that a feed inlet 2 is formed in the top end of the box body 1, a group of evenly distributed discharge holes 3 are formed in the middle of the side wall of the box body 1, a winding assembly 4 is arranged in the middle of the top end of the box body 1, a pull rope 5 is wound at the output end of the winding assembly 4, the other end of the pull rope 5 stretches into the box body 1 and is connected with a lifting cylinder 6, an opening is formed in the bottom end of the lifting cylinder 6, a spray hole 7 is formed in the side wall of the top end of the lifting cylinder 6, a motor 8 is arranged in the lifting cylinder 6, fan blades 9 are connected to the top end of the motor 8 through a rotating rod, a fixed ring 10 is connected to the inner wall of the box body 1 corresponding to the bottom end of the discharge hole 3, a woven net 11 is connected between the fixed ring 10 and the side wall of the top end of the lifting cylinder 6, and a limiting screen 12 matched with the lifting cylinder 6 is connected to the middle of the bottom surface of the box body 1; when the jelly cooling device in the prior art cools the jelly, the jelly in the cooling water tank is relatively static, so that the heat exchange efficiency of the jelly and surrounding water is lower, and although the heat exchange of the jelly and the cooling water can be promoted by stirring of the stirring equipment, the stirring equipment is easy to damage the formed jelly, and the processing quality of the jelly is influenced; when the jelly is required to be cooled, the winding component 4 releases the pull rope 5 to enable the lifting cylinder 6 at the bottom of the jelly to fall into the limiting screen 12 and limit the jelly, at the moment, the woven mesh 11 between the lifting cylinder 6 and the fixed ring 10 is in a funnel shape with the upper part wide and the lower part narrow, then the jelly is put into the box body 1 containing cooling water from the feeding port 2, meanwhile, the motor 8 drives the fan blades 9 to rotate, so that the fan blades 9 can continuously suck the cooling water at the bottom end of the lifting cylinder 6 and convey the cooling water upwards to the spray hole 7 for spraying, the cooling water in the box body 1 continuously circulates in the vertical direction under the action of the lifting cylinder 6, thereby promoting the heat exchange of the cooling water and the jelly, reducing the damage of the jelly in the cooling process, and enabling the woven mesh 11 to form a funnel shape with the upper part narrow and the lower part wide through the pull rope 5 after the jelly is cooled, thereby enabling the jelly taken up by the woven mesh 11 to flow out from the discharging port 3 and be convenient for entering the next procedure after the jelly is cooled.

The injection direction of the injection hole 7 is oriented obliquely downwards; when the woven mesh 11 is driven by the lifting cylinder 6 to discharge, the fan blade 9 which continuously rotates pumps air at the bottom end of the lifting cylinder 6 to the spray hole 7 to spray, and the direction of the air flow sprayed by the spray hole 7 is consistent with the inclined plane of the woven mesh 11 at the moment, so that the air flow sprayed by the spray hole 7 can be used for blowing off the fished-up jelly on the woven mesh 11, the collection of the jelly is promoted, meanwhile, the air flow at the spray hole 7 can be used for promoting the cooling and drying of the jelly, and water drops on the woven mesh 11 can be blown off, the residue of cooling water on the surface of the jelly is reduced, and the processing quality of the jelly is improved.

A limiting piece 13 is connected to the inner wall of the lifting cylinder 6 corresponding to one side of the rotating rod, and an impact block 14 matched with the limiting piece 13 is connected to the side wall of the rotating rod on one side of the limiting piece 13 through a traction rope; when the lifting cylinder 6 is lifted from the cooling water surface, the impact block 14 can continuously impact the limiting piece 13 under the drive of the rotating rod, so that the surface of the lifting cylinder 6 and the woven mesh 11 shake, the falling and collection of jelly on the woven mesh 11 are promoted, and meanwhile, the throwing and falling of the jelly and water drops on the woven mesh 11 are also promoted.

The lifting cylinder 6 is characterized in that an adsorption block 15 is arranged on the limiting piece 13, an electromagnet 16 which can attract the adsorption block 15 is connected to the outer wall of the lifting cylinder 6 corresponding to the top end of the limiting piece 13, a supporting frame is connected to the inner wall of the lifting cylinder 6 at the bottom end of the limiting piece 13, and the limiting piece 13 is connected with the supporting frame through a spring and can freely slide in the lifting cylinder 6; when the bottom end of the lifting cylinder 6 stretches into the cooling liquid, a gap exists between the limiting piece 13 and the rotating impact block 14 under the tensile force of the spring, the resistance generated by the rotation of the limiting piece 13 to the rotating rod is reduced, meanwhile, when the lifting cylinder 6 stretches out of the cooling liquid and needs to drive the woven mesh 11 to shake, the electromagnet 16 works and drives the limiting piece 13 to move towards one side close to the impact block 14 through the attraction and adsorption block 15, and accordingly the rotating rod drives the woven mesh 11 to shake smoothly through the impact block 14 when rotating.

The limiting piece 13 is made of elastic membrane materials, an elastic body 17 is connected between the limiting piece 13 and the inner wall of the lifting barrel 6, a racket rod 18 is rotatably connected to the outer wall of the lifting barrel 6 on one side of the limiting piece 13, a flexible bag 19 is connected between the bottom end of the racket rod 18 and the outer wall of the lifting barrel 6 on one side, and an air passage 20 which is communicated with the flexible bag 19 and the inner cavity of the limiting piece 13 is formed in the side wall of the lifting barrel 6; when the impact piece 14 is not required to collide with the limiting piece 13, the limiting piece 13 made of the elastic membrane is deformed to one side far away from the impact piece 14 under the action of the spring, when the woven mesh 11 is required to be driven to shake through rotation of the rotating rod, the electromagnet 16 can attract the adsorption piece 15, the limiting piece 13 is reset to the position where the impact piece 14 collides, meanwhile, when the impact piece 14 extrudes the limiting piece 13, air in the limiting piece flows into the telescopic bag 19 through the air channel 20, the telescopic bag 19 drives the racket rod 18 to rotate after being stretched, the racket rod 18 can play a role of beating the woven mesh 11 in the subsequent resetting process, and the shaking effect of the woven mesh 11 is further promoted.

A push rod 21 is arranged on the inner wall of the lifting cylinder 6 at the top end of the discharge hole 3, the bottom end of the push rod 21 is connected with an annular plate 22 capable of plugging the discharge hole 3, the bottom end of the feed inlet 2 is connected with an arc-shaped material guiding cavity 23, and the bottom end of the material guiding cavity 23 extends to the middle part of the box body 1; before the jelly gets into inside box 1, push rod 21 control annular plate 22 carries out the shutoff to discharge gate 3, drives the middle part of mesh grid 11 through lift cylinder 6 simultaneously and upwards jack-up, and the jelly that flows in from feed inlet 2 can follow the stable flow of guide chamber at the middle part top of mesh grid 11 this moment to constantly flow down along the inclined plane of mesh grid 11, reduce the jelly and directly throw into box 1 from feed inlet 2, lead to the jelly to drop from higher position and take place the condition of damage.

A diversion hole 24 communicated with the lifting cylinder 6 at one side of the spray hole 7 is formed in the inner wall of the lifting cylinder 6, the spray direction of the diversion hole 24 is inclined upwards, and control valves 25 are respectively arranged in the spray hole 7 and the diversion hole 24; when the woven mesh 11 is lowered into cooling water to cool the jelly, the control valve 25 in the diversion hole 24 is opened, and the control valve 25 in the spray hole 7 is closed, so that water flow sprayed obliquely upwards from the inside of the lifting cylinder 6 can spray the jelly on one side upwards, and meanwhile, the jelly can slide to the position of the diversion hole 24 along the inclined surface of the woven mesh 11, so that the jelly can be turned up in the cooling water continuously to move, and the cooling efficiency of the jelly is further improved.

Embodiment two:

as shown in fig. 4, in comparative example one, another embodiment of the present utility model is: the bottom of the woven mesh 11 is connected with a group of flexible pipes 26 which are mutually communicated, one side of the flexible pipe 26 facing the woven mesh 11 is provided with a plurality of air holes, the flexible pipe 26 is connected with the air outlet end of an external air pump through an air pipe, and the air inlet end of the air pump is communicated with a cold air source; the air pump can convey the cold air at the cold air source into the flexible pipe 26 and spray the cold air at the position of the woven mesh 11 through the air holes on the surface of the flexible pipe, so that the jelly at the position of the woven mesh 11 can be directly cooled, meanwhile, the movement of the jelly in cooling water can be promoted, and the cooling efficiency of the jelly is further improved.

The flexible pipe 26 is provided with a group of concave parts 27, the width of the concave parts 27 is gradually increased from inside to outside, and the positions of the woven mesh 11 corresponding to the concave parts 27 are attached to the concave parts 27; the jelly can flow into the woven mesh 11 at the concave part 27, and the concave part 27 arranged at the moment can increase the air injection area of the flexible pipe 26 to the jelly, so that the jelly can be cooled more rapidly.

A group of mutually attracted magnetic blocks 28 are symmetrically connected to the side wall of the concave part 27; when the middle part of the woven mesh 11 moves upwards gradually, the magnetic blocks 28 attracted to each other are instantaneously separated along with the continuous stretching of the woven mesh 11 and the flexible pipe 26, and drive the flexible pipe 26 and the woven mesh 11 to extend and shake, so that the discharge of jelly is further promoted, the residual moisture on the jelly and the woven mesh 11 is reduced, and the processing quality of the jelly is improved.

Working principle: when the jelly needs to be cooled, the winding component 4 releases the pull rope 5 to enable the lifting cylinder 6 at the bottom of the jelly to fall into the limiting screen 12 and limit the jelly, at the moment, the woven mesh 11 between the lifting cylinder 6 and the fixed ring 10 is in a funnel shape with the upper part wide and the lower part narrow, then the jelly is put into the box body 1 containing cooling water from the feed inlet 2, meanwhile, the motor 8 drives the fan blades 9 to rotate, so that the fan blades 9 can continuously suck the cooling water at the bottom end of the lifting cylinder 6 and convey the cooling water upwards to the spray hole 7 for spraying, the cooling water in the box body 1 continuously circulates in the vertical direction under the action of the lifting cylinder 6, thereby promoting the heat exchange of the cooling water and the jelly, reducing the damage of the jelly in the cooling process, and after the jelly is cooled, the winding component 4 pulls the lifting cylinder 6 and the middle part of the woven mesh 11 to move upwards through the pull rope 5, so that the woven mesh 11 forms a funnel shape with the upper part narrow and the lower part wide, and the jelly can flow out from the discharge hole 3, and the jelly which is convenient to cool enters the next procedure; when the woven mesh 11 is driven by the lifting cylinder 6 to discharge, the fan blades 9 which continue to rotate pump air at the bottom end of the lifting cylinder 6 to the spray holes 7 to spray, and the direction of the air flow sprayed by the spray holes 7 is consistent with the inclined plane of the woven mesh 11 at the moment, so that the air flow sprayed by the spray holes 7 can be used for blowing off the fished-up jelly on the woven mesh 11 to promote the collection of the jelly, and meanwhile, the air flow at the spray holes 7 can be used for promoting the cooling and drying of the jelly, and water drops on the woven mesh 11 can be blown off, so that the residue of cooling water on the surface of the jelly is reduced, and the processing quality of the jelly is improved; when the lifting cylinder 6 is lifted from the cooling water surface, the impact block 14 can continuously impact the limiting piece 13 under the drive of the rotating rod, so that the surface of the lifting cylinder 6 and the woven mesh 11 shake, the falling and collection of jelly on the woven mesh 11 are promoted, and meanwhile, the falling of the jelly and water drops on the woven mesh 11 are also promoted; when the bottom end of the lifting cylinder 6 stretches into the cooling liquid, a gap exists between the limiting piece 13 and the rotating impact block 14 under the tensile force of the spring, so that the resistance generated by the rotation of the limiting piece 13 to the rotating rod is reduced, and when the lifting cylinder 6 stretches out of the cooling liquid and needs to drive the woven mesh 11 to shake, the electromagnet 16 works and drives the limiting piece 13 to move to the side close to the impact block 14 through the attraction and adsorption block 15, so that the rotating rod can drive the woven mesh 11 to shake smoothly through the impact block 14 when rotating; when the impact piece 14 is not required to collide with the limiting piece 13, the limiting piece 13 made of the elastic film is deformed to one side far away from the impact piece 14 under the action of a spring, when the woven mesh 11 is required to be driven to shake through rotation of the rotating rod, the electromagnet 16 can reset to the position where the impact piece 14 collides through attraction of the adsorption piece 15, meanwhile, when the impact piece 14 extrudes the limiting piece 13, air in the limiting piece 13 flows into the telescopic bag 19 through the air passage 20, so that the telescopic bag 19 drives the racket rod 18 to rotate after being stretched, the racket rod 18 can play a role of beating the woven mesh 11 in the subsequent resetting process, and the shaking effect of the woven mesh 11 is further promoted; before the jelly enters the box body 1, the push rod 21 controls the annular plate 22 to plug the discharge hole 3, and simultaneously drives the middle part of the woven mesh 11 to jack up upwards through the lifting cylinder 6, so that the jelly flowing in from the feed inlet 2 can stably flow at the top end of the middle part of the woven mesh 11 along the guide cavity and continuously flow down along the inclined surface of the woven mesh 11, and the situation that the jelly falls down from a higher position to be damaged due to the fact that the jelly is directly put into the box body 1 from the feed inlet 2 is reduced; when the woven mesh 11 is lowered into cooling water to cool the jelly, the control valve 25 in the diversion hole 24 is opened, and the control valve 25 in the spray hole 7 is closed, so that water flow sprayed obliquely upwards from the inside of the lifting cylinder 6 can spray the jelly on one side upwards, and meanwhile, the jelly can slide to the position of the diversion hole 24 along the inclined plane of the woven mesh 11, so that the jelly can be turned up and swim in the cooling water continuously, and the cooling efficiency of the jelly is further improved; the air pump can convey the cold air at the cold air source into the flexible pipe 26 and spray the cold air at the position of the woven mesh 11 through the air holes on the surface of the flexible pipe, so that the jelly at the position of the woven mesh 11 can be directly cooled, and meanwhile, the movement of the jelly in cooling water can be promoted, and the cooling efficiency of the jelly is further improved; the jelly can flow into the woven mesh 11 at the concave part 27, and the concave part 27 arranged at the moment can increase the air injection area of the flexible pipe 26 on the jelly, so that the jelly can be cooled more rapidly; when the middle part of the woven mesh 11 moves upwards gradually, the magnetic blocks 28 attracted to each other are instantaneously separated along with the continuous stretching of the woven mesh 11 and the flexible pipe 26, and drive the flexible pipe 26 and the woven mesh 11 to extend and shake, so that the discharge of jelly is further promoted, the residual moisture on the jelly and the woven mesh 11 is reduced, and the processing quality of the jelly is improved.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the foregoing embodiments, and that the foregoing embodiments and description are merely illustrative of the principles of this utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, and these changes and modifications fall within the scope of the utility model as hereinafter claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims

1. A rapid cooling device for jelly production comprises a box body (1); the method is characterized in that: the novel automatic lifting device is characterized in that a feed inlet (2) is formed in the top end of the box body (1), a group of evenly distributed discharge holes (3) are formed in the middle of the side wall of the box body (1), a winding component (4) is mounted in the middle of the top end of the box body (1), a pull rope (5) is wound at the output end of the winding component (4), the other end of the pull rope (5) stretches into the box body (1) and is connected with a lifting cylinder (6), an opening is formed in the bottom end of the lifting cylinder (6), jet holes (7) are formed in the side wall of the top end of the lifting cylinder (6), a motor (8) is mounted in the middle of the lifting cylinder (6), fan blades (9) are connected to the top end of the motor (8) through rotating rods, a fixed ring (10) is connected to the inner wall of the box body (1) corresponding to the bottom end of the discharge hole (3), a woven net (11) is connected between the fixed ring (10) and the side wall of the top end of the lifting cylinder (6), and the middle of the bottom surface of the box body (1) is connected with a limit net plate (12) matched with the lifting cylinder (6).

The jet direction of the jet orifice (7) faces obliquely downwards;

a limiting piece (13) is connected to the inner wall of the lifting cylinder (6) corresponding to one side of the rotating rod, and an impact block (14) matched with the limiting piece (13) is connected to the side wall of the rotating rod on one side of the limiting piece (13) through a traction rope;

be equipped with on locating part (13) and adsorb piece (15), be connected with on the lifting cylinder (6) outer wall that locating part (13) top corresponds can with adsorb electromagnet (16) that piece (15) attracts mutually, be connected with the support frame on lifting cylinder (6) inner wall of locating part (13) bottom, locating part (13) link to each other and can freely slide in lifting cylinder (6) inside through the spring with the support.

2. A rapid cooling device for jelly production according to claim 1, characterized in that: the limiting piece (13) is made of elastic membrane materials, an elastic body (17) is connected between the limiting piece (13) and the inner wall of the lifting cylinder (6), a racket rod (18) is rotatably connected on the outer wall of the lifting cylinder (6) at one side of the limiting piece (13), a telescopic bag (19) is connected between the bottom end of the racket rod (18) and the outer wall of the lifting cylinder (6) at one side, and an air passage (20) which is communicated with the telescopic bag (19) and the inner cavity of the limiting piece (13) is arranged in the side wall of the lifting cylinder (6).

3. A rapid cooling device for jelly production according to claim 1, characterized in that: install push rod (21) on the lift section of thick bamboo (6) inner wall on discharge gate (3) top, push rod (21) bottom is connected with annular plate (22) that can carry out shutoff to discharge gate (3), the bottom of feed inlet (2) is connected with curved guide chamber (23), the bottom in guide chamber (23) stretches to box (1) middle part.

4. A rapid cooling device for jelly production according to claim 1, characterized in that: the inner wall of the lifting cylinder (6) at one side of the spray hole (7) is provided with a diversion hole (24) communicated with the lifting cylinder, the spray direction of the diversion hole (24) is inclined upwards, and control valves (25) are respectively arranged in the spray hole (7) and the diversion hole (24).

5. A rapid cooling device for jelly production according to claim 1, characterized in that: the bottom of the woven mesh (11) is connected with a group of flexible pipes (26) which are mutually communicated, a plurality of air holes are formed in one side, facing the woven mesh (11), of the flexible pipes (26), the flexible pipes (26) are connected with the air outlet end of an external air pump through an air conveying pipe, and the air inlet end of the air pump is communicated with a cold air source.

6. A rapid cooling device for jelly production according to claim 5, characterized in that: the flexible pipe (26) is provided with a group of concave parts (27), the width of the concave parts (27) is gradually increased from inside to outside, and the positions of the woven mesh (11) corresponding to the concave parts (27) are attached to the concave parts (27).

7. The rapid cooling device for jelly production according to claim 6, wherein: a group of mutually attractive magnetic blocks (28) are symmetrically connected to the side wall of the concave part (27).