CN219014735U - Improved jam heat exchange cooling device - Google Patents

Abstract

The utility model discloses an improved jam heat exchange cooling device, which comprises a base component, a double-layer tank body component obliquely arranged on the base component, an internal cooling system, a driving component and an external circulation refrigerating system for providing refrigerating fluid for the internal cooling system, wherein the base component is provided with a plurality of cooling units; the double-layer tank body assembly comprises an outer tank body, an inner tank body, a hollow shaft, a feeding pipe and a discharging pipe; the internal cooling system includes a plurality of serpentine internal cooling tubes; the driving component is arranged on the outer side of the hollow shaft, is connected with the hollow shaft through a transmission component and provides rotary driving force for the hollow shaft; the external circulation refrigerating system is communicated with the hollow shaft and the external cooling coil pipe through pipelines. The utility model has the advantages that the heat exchange area is increased by arranging the outer cooling coil pipe, the heat exchange efficiency is improved, and the jam is more uniform by arranging the inner cooling pipe with the cooling and stirring functions; the cooling pipe adopts a copper pipe coated by FeSO4, so that corrosion can be effectively prevented, and the service life of the pipeline is prolonged.

Description

Improved jam heat exchange cooling device

Technical Field

The embodiment of the utility model belongs to the technical field of foods, and particularly relates to an improved jam heat exchange cooling device.

Background

The jam is prepared by mixing fruit, sugar and acidity regulator with gel substance, and is a method for preserving fruit for a long time. The jam is required to be heated in the production process and then is cooled by the heat exchange device, and the prior art discloses an improved jam heat exchange cooling device, and the heat exchange operation is only carried out by the cooling coil pipe which is fixedly arranged, so that the heat exchange efficiency is poor.

Disclosure of Invention

In response to the above-identified deficiencies or improvements in the art, the present utility model provides an improved jam heat exchange cooling device.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

an improved jam heat exchange cooling device comprises a base assembly, a double-layer tank assembly obliquely arranged on the base assembly, an internal cooling system, a driving assembly and an external circulation refrigerating system for providing refrigerating fluid for the internal cooling system;

the double-layer tank body assembly comprises an outer tank body, an inner tank body, a hollow shaft, a feeding pipe and a discharging pipe; two ends of the hollow shaft extend out of the outer wall of the outer tank body; the inner tank body is fixedly arranged in the outer tank body, and the central axis of the inner tank body coincides with the central axis of the outer tank body; the hollow shaft is arranged on the central axis of the outer tank body, penetrates through the outer tank body and the inner tank body, and can rotate around the central axis of the outer tank body; the feeding pipe and the discharging pipe are respectively vertically inserted into the outer wall of the outer tank body from two sides and are directly communicated with the inner tank body;

the internal cooling system includes a plurality of serpentine internal cooling tubes; the inner cooling pipes are circumferentially and uniformly and fixedly arranged on the upper side and the lower side of the hollow shaft, both ends of each inner cooling pipe are communicated with the hollow shaft, the inner cooling system further comprises outer cooling coils arranged in the interlayers of the outer tank body and the inner tank body, and the outer cooling coils are spirally arranged close to the outer surface of the inner tank body;

the driving component is arranged on the outer side of the hollow shaft, is connected with the hollow shaft through a transmission component and provides rotary driving force for the hollow shaft;

the external circulation refrigerating system is communicated with the hollow shaft and the external cooling coil pipe through pipelines.

Further, the external circulation refrigerating system comprises a liquid storage tank filled with cooling liquid, a refrigerator, a pump, a return pipe, a conveying pipe and an external cooling coil pipe;

the return pipe and the delivery pipe are respectively sleeved at two ends of the hollow shaft extending to the outer tank body; the liquid storage tank, the refrigerator and the pump are sequentially and fixedly arranged above the outer tank body from left to right, the liquid storage tank and the refrigerator are connected together through a first conduit parallel to the outer wall of the outer tank body, and the inside of the liquid storage tank and the inside of the refrigerator are mutually communicated; the refrigerator and the pump are connected together through a second conduit parallel to the outer wall of the outer tank body, the inside of the refrigerator is communicated with each other, the right end of the return pipe is communicated with the liquid storage tank, and the left end of the conveying pipe is communicated with the pump; two ends of the outer cooling coil pipe are connected with two outer cooling coil pipe pipes which extend upwards perpendicular to the outer wall of the outer tank body, and the two outer cooling coil pipe pipes extend to the upper part of the outer tank body and are respectively communicated with the return pipe and the conveying pipe.

Further, the base subassembly includes base, a extension board, no. two extension boards: the first support plate and the second support plate are different in height and are respectively and fixedly arranged on two sides of the top surface of the base; the side outer wall of the outer tank body is fixedly connected with the top end of the first support plate and the second support plate.

Further, the driving assembly comprises a driving motor and a transmission part; the transmission part comprises a driving gear and a driven gear, the driving motor is fixedly arranged on one side of the outer tank body, the driving gear is fixedly sleeved on an output shaft of the driving motor, the driven gear is fixedly sleeved on the hollow shaft, and the driving gear is meshed with the driven gear.

Furthermore, the both sides of the outer wall are around the inner tank body are based on hollow shaft as center fixed mounting has the solid fixed ring, and one side that two solid fixed rings kept away from each other all is with the inner wall fixed connection of outer tank body.

Further, the right side of the outer wall of the outer tank body is fixedly provided with a fixing plate, the fixing plate is provided with a hole corresponding to the outer diameter of the conveying pipe, and the conveying pipe penetrates through the hole in the fixing plate.

Furthermore, a fixing frame is longitudinally and fixedly arranged on the hollow shaft along the axis of the hollow shaft, and the inner cooling pipe is fixedly connected with the fixing frame.

Further, copper pipes coated by FeSO4 are adopted as the inner cooling pipe and the outer cooling coil;

further, a pressure gauge is arranged on the conveying pipe or the return pipe or the first conduit or the second conduit.

In general, the above technical solutions conceived by the present utility model, compared with the prior art, enable the following beneficial effects to be obtained:

(1) According to the improved jam heat exchange cooling device, the outer cooling coil is arranged on the surface of the inner tank body, so that the heat exchange area is increased, and the heat exchange efficiency is improved;

(2) According to the improved jam heat exchange cooling device, the inner cooling pipe with the cooling and stirring functions is arranged, so that the heat exchange efficiency is improved, and jam is more uniform;

(3) According to the improved jam heat exchange cooling device, the cooling pipe adopts the copper pipe coated with FeSO4, so that corrosion can be effectively prevented, and the service life of a pipeline is prolonged.

Drawings

FIG. 1 is a schematic perspective view of an improved jam heat exchange cooling device according to an embodiment of the present utility model;

FIG. 2 is a cross-sectional view of an improved jam heat exchange cooling device according to one embodiment of the utility model;

fig. 3 is a schematic structural diagram of a portion a of an improved jam heat exchange cooling device according to an embodiment of the utility model.

Like reference numerals denote like technical features throughout the drawings, in particular: the device comprises a 1-ball base, a 2-first support plate, a 3-second support plate, a 4-inner tank body, a 5-outer tank body, a 6-feed pipe, a 7-discharge pipe, an 8-hollow shaft, a 9-inner cooling pipe, a 10-driving motor, a 11-driving gear, a 12-driven gear, a 13-liquid storage tank, a 14-refrigerator, a 15-pump, a 16-first guide pipe, a 17-second guide pipe, a 18-return pipe, a 19-conveying pipe, a 20-outer cooling coil pipe, a 21-outer cooling coil pipe, a 22-fixing frame, a 23-fixing plate, a 24-fixing ring and a 25-pressure gauge.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

An improved jam heat exchange cooling device comprises a base component, a double-layer tank component obliquely arranged on the base component, an internal cooling system, a driving component and an external circulation refrigerating system for providing refrigerating fluid for the internal cooling system

Referring to fig. 1, the base assembly includes a base 1, a first support plate 2, a second support plate 3: the first support plate 2 and the second support plate 3 are different in height and are respectively and fixedly arranged on two sides of the top surface of the base 1; the lateral outer wall of the outer tank body 5 is fixedly connected with the top ends of the first support plate 2 and the second support plate 3.

Referring to fig. 1-2, the double-layer tank assembly comprises an outer tank 5, an inner tank 4, a hollow shaft 8, a feed pipe 6 and a discharge pipe 7; two ends of the hollow shaft 8 extend out of the outer wall of the outer tank body 5; the inner tank body 4 is fixedly arranged inside the outer tank body 5, and the central axis of the inner tank body is coincident with the central axis of the outer tank body 5; the hollow shaft 8 is arranged on the central axis of the outer tank body 5 and penetrates through the outer tank body 5 and the inner tank body 4, and the hollow shaft 8 can rotate around the central axis of the outer tank body 5; the feed pipe 6 and the discharge pipe 7 are respectively vertically inserted into the outer wall of the outer tank body 5 from two sides and are directly communicated with the inner tank body 4;

referring to fig. 2, the internal cooling system includes a plurality of serpentine internal cooling tubes 9; the inner cooling pipes 9 are uniformly and fixedly arranged on the upper side and the lower side of the hollow shaft 8 in the circumferential direction, both ends of each inner cooling pipe 9 are communicated with the hollow shaft, the inner cooling system further comprises an outer cooling coil 20 arranged in an interlayer of the outer tank body 5 and the inner tank body 4, the outer cooling coil 20 is tightly attached to the outer surface of the inner tank body and is spirally arranged, the heat exchange area is increased, and the heat exchange efficiency is improved;

referring to fig. 3, the driving assembly is disposed on the outer side of the hollow shaft 8, and is connected with the hollow shaft 8 through a transmission component and provides a rotational driving force for the hollow shaft 8, and the driving assembly includes a driving motor 10 and a transmission component: the transmission part comprises a driving gear 11 and a driven gear 12, the driving motor 10 is fixedly arranged on one side of the outer tank body 5, the driving gear 11 is fixedly sleeved on an output shaft of the driving motor 10, the driven gear 12 is fixedly sleeved on the hollow shaft 8, and the driving gear 11 is meshed with the driven gear 12, so that the hollow shaft 8 can be driven to rotate.

Referring to fig. 2, the external circulation refrigeration system is communicated with the hollow shaft 8 and the external cooling coil 20 through pipelines, and comprises a liquid storage tank 13 filled with cooling liquid, a refrigerator 14, a pump 15, a return pipe 18, a conveying pipe 19 and an external cooling coil pipe 21: the return pipe 18 and the delivery pipe 19 are respectively sleeved at two ends of the hollow shaft 8 extending to the outer tank body 5; the liquid storage tank 13, the refrigerator 14 and the pump 15 are sequentially and fixedly arranged above the outer tank body 5 from left to right, the liquid storage tank 13 and the refrigerator 14 are connected together through a first conduit 16 parallel to the outer wall of the outer tank body 5, and the interiors of the liquid storage tank 13 and the refrigerator 14 are communicated with each other; the refrigerator 14 and the pump 15 are connected together through a second conduit 17 parallel to the outer wall of the outer tank body 5, the interiors of the refrigerator 14 and the pump 15 are communicated with each other, the right end of a return pipe 18 is communicated with the liquid storage tank 13, and the left end of a conveying pipe 19 is communicated with the pump 15; two ends of the outer cooling coil pipe 20 are connected with two outer cooling coil pipe 21 which extend upwards perpendicular to the outer wall of the outer tank body 5, and the two outer cooling coil pipe 21 extend to the upper side of the outer tank body 5 and are respectively communicated with the return pipe 18 and the conveying pipe 19.

Referring to fig. 2, the two sides of the left and right outer walls of the inner tank 4 are fixedly provided with fixing rings 24 based on the hollow shaft 8, and the sides of the two fixing rings 24 away from each other are fixedly connected with the inner wall of the outer tank 5, so that the inner tank 4 can be stably supported by the fixing rings 24, and the inner tank 4 can maintain good stability in the working process. The right side of outer wall of outer jar body 5 fixed mounting has fixed plate 23, has the trompil that suits with conveyer pipe 19 external diameter on the fixed plate 23, and conveyer pipe 19 passes the trompil on the fixed plate 23, can provide stable support to conveyer pipe 19 through the fixed plate 23. The hollow shaft 8 is longitudinally and fixedly provided with a fixing frame 22 along the axis, the inner cooling pipe 9 is fixedly connected with the fixing frame 22, stable support can be provided for the inner cooling pipe 9 through the fixing frame 22, and jam in the inner tank 4 can be stirred when the hollow shaft 8 rotates.

To prevent corrosion, the inner cooling tube 9 and the outer cooling coil 20 use copper tubes coated with FeSO 4; and the conveying pipe 19 or the return pipe 18 or the first conduit 16 or the second conduit 17 is provided with a pressure gauge 25 for monitoring the pressure of the pipeline, preventing the pipeline pressure from being too high and reducing the service life of the equipment.

Working principle: in use, the drive motor 10 is first started by switching on the power supply. The jam that needs to carry out heat exchange is carried to interior jar body 4 through inlet pipe 6 in refrigerator 14 and pump 15, driving motor 10 can drive hollow shaft 8 through driving gear 11 and driven gear 12 and rotate, thereby can control mount 22 and a plurality of interior cooling tube 9 to turn over and mix the operation to the jam, pump 15 draws the coolant in the liquid reserve tank 13, cool down the coolant under the effect of refrigerator 14, then carry it to hollow shaft 8 through conveyer pipe 19 under the effect of pump 15, coolant in hollow shaft 8 can get into interior cooling tube 9 along with the rotation of hollow shaft 8, thereby can accomplish the heat exchange operation to the jam in-process of turning over and mixing, coolant in conveyer pipe 19 gets into outer cooling coil 20 simultaneously, thereby can cool down interior jar body 4, along with the continuous work of pump 15 and refrigerator 14 can make the coolant that accomplishes the heat exchange flow back to liquid reserve tank 13 through back 18, then refrigerate through refrigerator 14 again, thereby can form the circulation circuit, after the heat exchange is accomplished will follow discharging pipe 7 and can.

It will be readily appreciated by those skilled in the art that the foregoing description is merely a preferred embodiment of the utility model and is not intended to limit the utility model, but any modifications, equivalents, improvements or alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

Claims (9)

1. The improved jam heat exchange cooling device is characterized by comprising a base assembly, a double-layer tank body assembly obliquely arranged on the base assembly, an internal cooling system, a driving assembly and an external circulation refrigerating system for supplying refrigerating fluid to the internal cooling system;

the double-layer tank body assembly comprises an outer tank body (5), an inner tank body (4), a hollow shaft (8), a feeding pipe (6) for inputting jam and a discharging pipe (7) for outputting jam; two ends of the hollow shaft (8) extend out of the outer wall of the outer tank body (5); the inner tank body (4) is fixedly arranged in the outer tank body (5) and the central axis of the inner tank body is coincident with the central axis of the outer tank body (5); the hollow shaft (8) is arranged on the central axis of the outer tank body (5) and penetrates through the outer tank body (5) and the inner tank body (4), and the hollow shaft (8) can rotate around the central axis of the outer tank body (5); the feed pipe (6) and the discharge pipe (7) are respectively vertically inserted into the outer wall of the outer tank body (5) from two sides and are directly connected into the inner tank body (4);

the internal cooling system comprises a plurality of serpentine internal cooling pipes (9) for cooling and stirring the jam; the inner cooling pipes (9) are circumferentially and uniformly and fixedly arranged on the upper side and the lower side of the hollow shaft (8), both ends of each inner cooling pipe (9) are communicated with the hollow shaft, the inner cooling system further comprises an outer cooling coil (20) arranged in an interlayer of the outer tank body (5) and the inner tank body (4), and the outer cooling coils (20) are spirally arranged close to the outer surface of the inner tank body;

the driving component is arranged on the outer side of the hollow shaft (8), is connected with the hollow shaft (8) through a transmission component and provides rotary driving force for the hollow shaft (8);

the external circulation refrigerating system is communicated with the hollow shaft (8) and the external cooling coil pipe (20) through pipelines.

2. An improved jam heat exchange cooling unit as in claim 1 wherein: the external circulation refrigerating system comprises a liquid storage tank (13) filled with cooling liquid, a refrigerator (14), a pump (15), a return pipe (18), a conveying pipe (19) and an external cooling coil pipe (21);

the return pipe (18) and the conveying pipe (19) are respectively sleeved with two ends of the hollow shaft (8) extending to the outer tank body (5); the liquid storage tank (13), the refrigerator (14) and the pump (15) are sequentially and fixedly arranged above the outer tank body (5) from left to right, the liquid storage tank (13) and the refrigerator (14) are connected together through a first conduit (16) parallel to the outer wall of the outer tank body (5), and the interiors of the liquid storage tank and the refrigerator are communicated with each other; the refrigerator (14) and the pump (15) are connected together through a second conduit (17) parallel to the outer wall of the outer tank body (5), the inside of the refrigerator is communicated with each other, the right end of a return pipe (18) is communicated with the liquid storage tank (13), and the left end of a conveying pipe (19) is communicated with the pump (15); two ends of the outer cooling coil pipe (20) are connected with two outer cooling coil pipe conduits (21) which extend upwards and are perpendicular to the outer wall of the outer tank body (5), and the two outer cooling coil pipe conduits (21) extend to the upper side of the outer tank body (5) and are respectively communicated with the return pipe (18) and the conveying pipe (19).

3. An improved jam heat exchange cooling unit as in claim 1 wherein: the base assembly comprises a base (1), a first support plate (2) and a second support plate (3): the first support plate (2) and the second support plate (3) are different in height and are respectively and fixedly arranged on two sides of the top surface of the base (1); the lateral outer wall of the outer tank body (5) is fixedly connected with the top ends of the first support plate (2) and the second support plate (3).

4. An improved jam heat exchange cooling unit as in claim 1 wherein: the driving assembly comprises a driving motor (10) and a transmission part; the transmission part comprises a driving gear (11) and a driven gear (12), the driving motor (10) is fixedly arranged on one side of the outer tank body (5), the driving gear (11) is fixedly sleeved on an output shaft of the driving motor (10), the driven gear (12) is fixedly sleeved on the hollow shaft (8), and the driving gear (11) is meshed with the driven gear (12).

5. An improved jam heat exchange cooling unit as in claim 1 wherein: the two sides of the left outer wall and the right outer wall of the inner tank body (4) are fixedly provided with fixing rings (24) based on a hollow shaft (8) as the center, and one sides of the two fixing rings (24) which are far away from each other are fixedly connected with the inner wall of the outer tank body (5).

6. An improved jam heat exchange cooling unit as in claim 1 wherein: the right side of the outer wall of the outer tank body (5) is fixedly provided with a fixing plate (23), the fixing plate (23) is provided with a hole corresponding to the outer diameter of the conveying pipe (19), and the conveying pipe (19) penetrates through the hole in the fixing plate (23).

7. An improved jam heat exchange cooling unit as in claim 1 wherein: the hollow shaft (8) is longitudinally and fixedly provided with a fixing frame (22) along the axis, and the inner cooling pipe (9) is fixedly connected with the fixing frame.

8. An improved jam heat exchange cooling unit as in any one of claims 1 to 7 wherein: the inner cooling pipe (9) and the outer cooling coil (20) adopt copper pipes coated by FeSO 4.

9. An improved jam heat exchange cooling unit as in claim 2 wherein: and a pressure gauge (25) is arranged on the conveying pipe (19) or the return pipe (18) or the first conduit (16) or the second conduit (17).

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