CN109631617B - Vermicelli cooling device - Google Patents

Abstract

A vermicelli cooling device relates to the field of food processing, and comprises a containing part, a lower sliding pipe and a cooling part, the containing part comprises an arc convex top, a radiation disc and a shunt turning surface, the arc convex top is an upper semi-spherical surface which is convex upwards, the radiation disc is an inclined plane extending from the edge of the arc convex top to the top and outwards, the diversion lower surface is an inclined circular table surface extending from the top to the bottom and inwards, the radiation disc is connected above the lower surface of the shunt rotor through a side rod, the side rod is a straight rod which vertically extends downwards from the lower edge of the radiation disc to the inner surface of the lower surface of the shunt rotor, the lower sliding pipe is a hollow straight pipe connected with the lower surface of the shunt rotor, the cooling part is used for cooling the wall surface of the lower sliding pipe, the vermicelli can be cooled evenly, so that individual vermicelli cannot be cooled, and the vermicelli is prevented from being adhered to each other before and after cooling.

Description

Vermicelli cooling device

Technical Field

The invention relates to the field of food processing, in particular to a vermicelli cooling device.

Technical Field

Vermicelli is a special traditional food with the characteristics of drying strand silk, which is prepared by taking sweet potatoes, potatoes and the like as raw materials and then carrying out processes such as slurry grinding, precipitation and the like on the sweet potatoes and the like. Among the numerous steps of the processing production of vermicelli, the cooling step belongs to the most central one-step, if the vermicelli cooling can not reach the effect, can make the vermicelli adhesion can't separate each other, causes very big influence to the finished product encapsulation of later stage. Therefore, the finished quality of the cooling process in the production and processing process of the vermicelli determines the finished product rate of the vermicelli.

Disclosure of Invention

The invention provides a vermicelli cooling device which can cool vermicelli evenly, avoid individual vermicelli from being cooled and prevent vermicelli from being adhered before and after cooling.

The technical purpose of the invention is realized by the following technical scheme: the utility model provides a vermicelli cooling device, wherein, includes and goes into portion, gliding runner and cooling part down, it includes that the arc is protruding, the radiation dish changes below with the reposition of redundant personnel to go into the portion of going into greatly, the arc is protruding last half-round sphere face that makes progress, the radiation dish is for certainly the slope plane of edge top-down, the outside extension of the arc is protruding, divide and flow and change the slope table surface that is top-down, inside extension below, the radiation dish pass through the side pole connect in divide the reposition of redundant personnel below the top, the side pole is for certainly the vertical downwardly extending of lower limb of radiation dish divides the straight-bar of the internal surface below changeing, the gliding runner is for connecting divide the hollow straight tube below changeing, the cooling part is used for the cooling down the wall of gliding runner.

Preferably, the lower diversion surface is further provided with a spiral sliding groove, and the spiral sliding groove is a groove which spirally extends downwards from top to bottom on the upper part of the inner side surface of the lower diversion surface.

Preferably, the cooling portion includes a sleeve wall portion, a water jet and a water inlet pipe, the sleeve wall portion is a sleeve surface extending outward from an outer wall surface of the lower slide pipe, vertically extending upward, and then connected to the lower slide pipe, the water jet is an opening penetrating inward from a joint of an upper edge of the lower slide pipe and the sleeve wall portion, and the water inlet pipe is connected to a lower edge of the sleeve wall portion.

Preferably, the sleeve wall portion further includes a lower punching chamber, the lower punching chamber is an upward convex cambered surface extending from an inner surface of an upper end of the sleeve wall portion to a side close to the water jet, and the lower punching chamber is inclined downward toward an inner side of the lower slide pipe in a direction close to the water jet.

Preferably, the air cooling part is further provided for cooling the lower slide pipe.

Preferably, the air cooling portion comprises a tight block sleeved outside the lower sliding pipe and a blowing pipeline located in the tight block, the blowing pipeline comprises an air inlet pipe, an ascending pipe and an adherence channel, the air inlet pipe is a horizontal hollow pipe located in the tight block, the ascending pipe is an arc-shaped pipeline from bottom to top and close to one side of the lower sliding pipe, and the adherence channel is a vertical pipeline extending from the tail end of the ascending pipe to two sides in the vertical direction.

Preferably, the upper pipe is provided with an air guide wall surface, and the air guide wall surface is an arc surface extending from the top to the bottom from the upper edge of the tail end of the upper pipe to the side close to the lower sliding pipe.

Preferably, the air-return cooling device further comprises a return air cooling cavity, wherein the return air cooling cavity is a cavity which is sunken from the outer wall surface of the adherence channel below the air guide wall surface to one side of the air inlet pipe.

Preferably, the air storage cavity is an annular cavity which is recessed from the outer wall surface of the adherence channel above the air guide wall surface to one side of the air inlet pipe and has a semicircular section.

In conclusion, the invention has the following beneficial effects: the vermicelli is combed uniformly through the radiation disc, and then the cooling part is used for carrying out water cooling on the vermicelli, so that the situation that individual vermicelli cannot be cooled is avoided, meanwhile, the air cooling part is used for carrying out secondary cooling on the vermicelli, and the vermicelli is prevented from being adhered to each other before and after being cooled.

Drawings

FIG. 1 is a schematic view of the overall structure of a vermicelli cooling device.

Fig. 2 is a front view of the structure of the vermicelli cooling device.

Fig. 3 is a schematic view of a spiral chute.

Fig. 4 is a sectional view of the cooling part.

FIG. 5 is a sectional view of the air cooling part.

In the figure: 11. arc convex tops, 12 radiation disks, 13 diversion rotary bottoms, 14 spiral chutes, 21, sleeve wall parts, 22, water spray nozzles, 23, lower punching cavities, 31, air inlet pipes, 32, upper walking pipes, 33, wall sticking channels, 4, air guide wall surfaces, 5, return air cooling cavities, 6 and air storage cavities.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Embodiment 1, as shown in fig. 1 to 5, at first, the vermicelli to be cooled is poured into the containing part, that is, the vermicelli contacts the arc convex top 11 first, the upward convex arc design can slow down the speed of the vermicelli sliding into the radiation disk 12, through the radiation disk 12, the vermicelli can be scattered and dropped to the diversion rotary lower surface 13 in multiple directions, so that a certain heat dissipation effect can be achieved, the vermicelli slides into the lower slide pipe from the diversion rotary lower surface 13 gradually, because the cooling part can cool down the lower slide pipe, the vermicelli moving in the lower slide pipe is cooled down again, and finally, the vermicelli cooled down through the outlet of the lower slide pipe is collected.

In particular, the lower diversion surface 13 is provided with a plurality of spiral chutes 14, when the vermicelli falls from the radiation disk 12 into the lower diversion surface 13, the vermicelli can slide into the lower sliding pipe along the spiral chutes 14, and the number of the spiral chutes 14 can be a plurality, and the spiral chutes 14 are circumferentially and symmetrically arranged on the lower diversion surface 13.

After the water is supplied to the water inlet pipe, water is accumulated on the sleeve wall part 21 from bottom to top so as to cool the wall surface of the lower sliding pipe, and after the sleeve wall part 21 is filled with water, the water is flushed into the lower sliding pipe from the water spray opening 22, and at the moment, the cooling water is contacted with the vermicelli so as to continuously cool the vermicelli.

The lower punching cavity 23 is beneficial to washing the cooling water along the falling direction of the vermicelli, and the damage to the surface of the vermicelli and even the breakage of the vermicelli caused by the opposite punching of the cooling water and the vermicelli are avoided.

Still there is the air cooling portion in the below of cooling portion, the air cooling portion is through blowing the air supply in the piece of hugging closely, and owing to hug closely the piece ring cover in the wall of slide down, so, cold wind blows in adherence passageway 33 through air-supply line 31 and ascending pipe 32, by the wall of slide down of adherence passageway 33 contact, cool off the slide down pipe, wherein, the upper end of adherence passageway 33 is the opening, the intercommunication atmosphere, so by the cold wind that ascending pipe 32 flowed into adherence passageway 33 through wind-guiding wall 4 first downstream, upwards discharge again, can reach better cooling effect.

Particularly, the return air cooling cavity 5 is used for carrying out rotary flow on high-temperature gas after the wall surface of the lower sliding pipe is cooled, the flow direction is that the high-temperature gas flows back to the edge close to one side of the upper sliding pipe 32 from the wall surface of the lower sliding pipe along the edge of the return air cooling cavity 5, the temperature of the edge is lower than that of the edge close to one side of the lower sliding pipe due to the fact that the return air cooling cavity is close to the upper sliding pipe 32, and finally the return air cooling cavity continues to move along the edge of the return air cooling cavity 5, is close to the wall surface. And finally, the gas enters the gas storage cavity 6, and the gas can be cooled by being flushed up after being diffused and cooled because the lower part of the gas storage cavity 6 is large in cavity.

Claims (6)

1. A vermicelli cooling device is characterized by comprising a containing part, a lower sliding pipe and a cooling part, wherein the containing part comprises an arc convex top (11), a radiation disc (12) and a shunting rotating bottom (13), the arc convex top (11) is an upper semi-spherical surface protruding upwards, the radiation disc (12) is an inclined plane extending outwards from the edge of the arc convex top (11) from top to bottom, the shunting rotating bottom (13) is an inclined circular table surface extending inwards from top to bottom, the radiation disc (12) is connected above the shunting rotating bottom (13) through a side rod, the side rod is a straight rod extending downwards from the lower edge of the radiation disc (12) to the inner surface of the shunting rotating bottom (13), the lower sliding pipe is a hollow straight pipe connected with the shunting rotating bottom (13), the cooling part is used for cooling the wall surface of the lower sliding pipe, and the air cooling part is used for cooling the lower sliding pipe, the forced air cooling portion include the ring cover in the tight piece that pastes in the slide pipe outside down with be located hug closely the blowing pipeline in the piece, the blowing pipeline includes air-supply line (31), upward pipe (32) and adherence passageway (33), air-supply line (31) are for being located hug closely the horizontal blank pipe in the piece, upward pipe (32) are for certainly the end of air-supply line (31) is from bottom to top, to being close to the arc pipeline that one side direction of gliding duct is close to meeting, adherence passageway (33) are for certainly the vertical pipeline of the end to vertical direction both sides extension of upward pipe (32), upward have wind-guiding wall face (4) on pipe (32), wind-guiding wall face (4) are for from top to top the end top edge top-down of upward pipe (32), to being close to the arcwall face that the extension of gliding duct one side down.

2. The vermicelli cooling device according to claim 1, wherein a spiral chute (14) is further formed on the diversion lower surface (13), and the spiral chute (14) is a groove which extends spirally downwards from the upper part of the inner side surface of the diversion lower surface (13) from top to bottom.

3. A vermicelli cooling device according to claim 1, wherein the cooling portion comprises a sleeve wall portion (21), a water jet (22) and a water inlet pipe, the sleeve wall portion (21) is a sleeve surface extending outward from the outer wall surface of the lower slide pipe, vertically extending upward and then being connected to the lower slide pipe, the water jet (22) is an opening penetrating inward from the joint of the lower slide pipe and the upper edge of the sleeve wall portion (21), and the water inlet pipe is connected to the lower edge of the sleeve wall portion (21).

4. A vermicelli cooling device according to claim 3 wherein said sleeve wall portion (21) further comprises a lower chamber (23), said lower chamber (23) being an upwardly convex surface extending from the inner surface of the upper end of said sleeve wall portion (21) to the side near said water jet (22), said lower chamber (23) being oriented obliquely downward toward the inside of said downslide pipe near said water jet (22).

5. The vermicelli cooling device according to claim 1, further comprising a return air cooling chamber (5), wherein the return air cooling chamber (5) is a cavity recessed from the outer wall of the adherence channel (33) below the air guide wall surface (4) to the side of the air inlet pipe (31).

6. The vermicelli cooling device according to claim 5, further comprising an air storage chamber (6), wherein the air storage chamber (6) is an annular cavity with a semicircular section, which is recessed from the outer wall of the adherence channel (33) above the air guide wall surface (4) to the side of the air inlet pipe (31).

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