CN217383561U - Energy transfer heat preservation water tank in vermicelli drying system - Google Patents

Energy transfer heat preservation water tank in vermicelli drying system Download PDF

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Publication number
CN217383561U
CN217383561U CN202221200912.XU CN202221200912U CN217383561U CN 217383561 U CN217383561 U CN 217383561U CN 202221200912 U CN202221200912 U CN 202221200912U CN 217383561 U CN217383561 U CN 217383561U
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China
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heat
water
barrel
pump
heat preservation
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丁德华
何才运
丁紫瑶
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Wuhan Chuangliyuan Energy Conservation And Environmental Protection Technology Co ltd
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Wuhan Chuangliyuan Energy Conservation And Environmental Protection Technology Co ltd
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    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/40Solar thermal energy, e.g. solar towers

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Abstract

The utility model discloses an energy transfer heat preservation water tank in a fine dried noodle drying system, which comprises a heat preservation barrel and an overflow port, the overflow port is penetrated inside and outside the upper side of the left end of the heat preservation barrel, vent holes are penetrated inside and outside the center of the top end of the heat preservation barrel, a water feeding pipe is penetrated inside and outside the right side of the center of the top end of the heat preservation barrel, the top end of the water feeding pipe is connected with a water feeding port, a heat exchange integration device is arranged on the upper side of the inner wall of the left end of the heat preservation barrel, the upper layer water energy in the heat preservation barrel can be rapidly heated by arranging the heat exchange integration device on the upper side of the inner wall of the left end of the heat preservation barrel, thereby coping with the production requirement, improving the heating efficiency, guaranteeing the normal production, guaranteeing the production efficiency, arranging a heat pump device on the right end of the heat preservation barrel by arranging a solar integration device on the lower side of the left end of the heat preservation barrel, leading the circulating water to be more environment-friendly and lower in cost, and leading the heat pump to be timely supplemented under the condition of poor sunlight and insufficient supply, and in time supply hot water to the inside upper strata of heat-preserving container, guarantee production.

Description

Energy transfer heat preservation water tank in vermicelli drying system
Technical Field
The utility model belongs to the technical field of holding water box is relevant, concretely relates to energy transfer holding water box among vermicelli drying system.
Background
The energy transfer heat preservation water tank comprises the following components: the solar water heater comprises a heat exchange integrated device, a heat storage water tank, a heat pump device, a heat exchange integrated device, an intelligent control system, a heat exchange integration device and the like, wherein the heat exchange integrated device receives solar radiation, converts collected solar radiation energy into heat energy, stops heating through a temperature sensor, a temperature controller, an electromagnetic valve, a water pump and other equipment when the water temperature reaches a set temperature, starts corresponding equipment when the supply is insufficient or the sunlight is poor, automatically converts the system operation mode into constant temperature circulation, and improves the heating efficiency.
The prior heat preservation water tank technology has the following problems: 1. generally, a rapid heating device is not arranged in the circulating water heating process, so that when a large amount of hot water is required in the production process, enough hot water is difficult to rapidly supply for production, the production is delayed, and the production efficiency is reduced; 2. the inside circulating water of heat-preserving container heats through the heating wire for the heating method of circulating water is very taken electric energy, and not environmental protection, thereby has improved manufacturing cost, can not in time provide sufficient hot water under the condition of the hot water supply of urgent need simultaneously, makes production can't obtain the guarantee, and the hot water after the heating of heating wire can not in time flow in the upper strata of heat-preserving container, makes hot water can not in time supply for the stoving room, has reduced hot water supply efficiency.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide an energy transfer holding water box among vermicelli drying system to solve the slow and untimely and heating with high costs problem of hot water supply of the rate of heating that provides among the above-mentioned background art.
In order to achieve the above purpose, the utility model provides a following technical scheme: an energy transfer heat preservation water tank in a fine dried noodle drying system comprises a heat preservation barrel and an overflow port, wherein the overflow port penetrates through the inside and the outside of the upper side of the left end of the heat preservation barrel, vent holes penetrate through the inside and the outside of the center of the top end of the heat preservation barrel, a water feeding pipe penetrates through the inside and the outside of the right side of the center of the top end of the heat preservation barrel, the top end of the water feeding pipe is connected with a water feeding port, a heat exchange integration device is arranged on the upper side of the inner wall of the left end of the heat preservation barrel, a partition plate is arranged on the lower side of the heat exchange integration device, a solar integration device is arranged on the lower side of the left end of the heat preservation barrel, a heat pump device is arranged at the right side of the heat pump device, a drying room is arranged on the right side of the heat preservation barrel, a water discharging pipe penetrates through the inside and the outside of the lower end of the heat preservation barrel, the heat exchange integration device comprises a medium inlet, a heat exchange pipe, a heat exchange sheet and a medium outlet are arranged on the inner wall of the upper side of the left end of the heat preservation barrel, the medium inlet right-hand member is connected with the heat exchange tube, the heat exchange tube outer end is connected with a plurality of heat exchanger fins, heat exchange tube left end downside is connected with the medium export, solar energy collection device includes that hot water exit tube, solar panel, circulating pump and cold water go into the pipe, it has the hot water exit tube to run through inside and outside the heat-preserving container left end downside, hot water exit tube lower extreme is connected with solar panel, solar panel lower extreme left side is connected with the cold water and goes into the pipe, be provided with the circulating pump in the middle of the cold water is gone into the pipe, heat pump device includes upper outlet pipe, heat pump, intake pump and lower floor oral siphon, it has the upper outlet pipe to run through inside and outside the heat-preserving container right-hand member upside, upper outlet pipe right-hand member is connected with the heat pump, heat pump left end downside is connected with the oral siphon of lower floor, be provided with the intake pump in the middle of the oral siphon of lower floor.
Preferably, the heat-insulating barrel consists of an inner barrel and an outer barrel, a heat-insulating layer is arranged between the inner barrel and the outer barrel, and the heat-insulating layer is made of polyurethane.
Preferably, a connecting hole penetrates through the center of the upper end of the partition plate from top to bottom, the partition plate divides the interior of the heat-preserving barrel into an upper layer and a lower layer, and the upper layer and the lower layer of the heat-preserving barrel are communicated through the connecting hole.
Preferably, the medium inlet conveys the heat medium to the interior of the heat exchange tube, the heat exchange tube and the heat exchange fins heat the water on the upper layer in the heat-insulating barrel by radiating the heat of the heat medium, the medium outlet discharges the cooled medium, and the left end of the medium inlet is connected with a start-stop control unit and can intelligently control the start and stop of the inflow of the heat medium.
Preferably, the cold water is gone into the pipe and is carried the inside solar panel of heating through the circulating pump with the inside cold water of the lowest floor of heat-preserving container, inside solar panel passed through the hot water exit tube and goes into the heat-preserving container with the log raft after heating, the inside start-stop control unit that is provided with of circulating pump, start-stop control unit opens according to opening of difference in temperature control circulating pump and stops.
Preferably, the lower floor's oral siphon passes through the intake pump and carries the inside heating pump of heat-preserving container inside with the lower floor's water of heat-preserving container, the inside upper strata of heat-preserving container is gone into to the water discharge after the heating pump will heat through upper outlet pipe, the intake pump is inside to be provided with to open and stop the control unit and can carry out intelligence to the intake pump by pattern data analysis and open and stop control.
Compared with the prior art, the utility model provides an energy transfer holding water box among vermicelli drying system possesses following beneficial effect:
1. the heat exchange integration device is arranged on the upper side of the inner wall of the left end of the heat preservation barrel, the heat medium heats the upper water in the heat preservation barrel through the heat exchange tube and the heat exchange sheet, the upper water in the heat preservation barrel can be quickly heated to a preset temperature, the inflow of the heat medium is closed through the intelligent start-stop unit, the hot water supply required by production is ensured, the heating efficiency is improved, the normal production is ensured, the production efficiency is ensured, the rapid heating device is not arranged in the original circulating water heating, so that when a large amount of hot water is required in the production process, it is difficult to rapidly supply enough hot water for production, thereby delaying production and reducing production efficiency, the upper layer water in the heat-insulating barrel can be quickly heated by arranging the heat exchange integrated device on the upper side of the inner wall of the left end of the heat-insulating barrel, therefore, the production needs are met, the heating efficiency is improved, the normal production is guaranteed, and the production efficiency is guaranteed.
2. The solar energy heat-preserving device is arranged at the lower side of the left end of the heat-preserving barrel, circulating water is conveyed to the interior of the solar panel through the circulating pump to be heated and then flows back to the lower layer of the interior of the heat-preserving barrel after being heated, so that the circulating water is more environment-friendly and has lower cost, thereby reducing the production cost, the heat pump device is arranged at the right end of the heat-preserving barrel, the circulating water can be continuously heated under the condition of poor sunlight, and the heated hot water can be directly sent to the upper layer of the interior of the heat-preserving barrel, thereby well making up the defects of the heating of the solar panel, ensuring the production, simultaneously reducing the length of a water circulating path, enabling the hot water to be more quickly supplied to a drying room, improving the hot water supply efficiency, ensuring the production efficiency, and originally heating the circulating water in the heat-preserving barrel through the heating wire, so that the heating mode of the circulating water is very electric energy-consuming and is not environment-friendly, thereby improving the production cost, simultaneously can not in time provide sufficient hot water under the condition of the hot water supply of urgent need, make production can't obtain the guarantee, and the hot water after the heating wire heating can not in time flow in the upper strata of heat-preserving container, make hot water can not in time supply for the stoving room, hot water supply efficiency has been reduced, through setting up solar energy integrated device at heat-preserving container left end downside, set up heat pump device at the heat-preserving container right-hand member, make the circulating water heating more environmental protection, the cost is lower, and the heat pump can in time supply under the not good and not enough circumstances of supply of sunshine, and in time supply hot water to the inside upper strata of heat-preserving container, guarantee production, improve supply efficiency, and the production efficiency is improved.
Drawings
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and do not constitute a limitation on the invention, and in the drawings:
fig. 1 is a schematic view of a front view cross-sectional structure of an energy transfer heat preservation water tank in a dried noodle drying system provided by the utility model;
fig. 2 is a schematic front view of the heat exchange integration device according to the present invention;
fig. 3 is a schematic front view of the solar energy collecting device according to the present invention;
fig. 4 is a schematic front view of the heat pump device according to the present invention;
in the figure: 1. a heat-preserving barrel; 2. an overflow port; 3. a heat exchange integrated device; 4. a partition plate; 5. a solar energy integration device; 6. a vent; 7. a water filling port; 8. a water feeding pipe; 9. a drying room; 10. heat exchange integration; 11. a heat pump device; 12. a drain pipe; 13. a media inlet; 14. a heat exchange pipe; 15. a heat exchanger fin; 16. a media outlet; 17. a hot water outlet pipe; 18. a solar panel; 19. a circulation pump; 20. cold water enters the pipe; 21. an upper layer water outlet pipe; 22. a heat pump; 23. a water inlet pump; 24. the lower floor is the inlet pipe.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Example one
Referring to fig. 1 and fig. 2, the present invention provides a technical solution: an energy transfer heat preservation water tank in a fine dried noodle drying system comprises a heat preservation barrel 1 and an overflow port 2, the overflow port 2 penetrates through the inside and outside of the upper side of the left end of the heat preservation barrel 1, the heat preservation barrel 1 consists of an inner barrel and an outer barrel, a heat insulation layer is arranged between the inner barrel and the outer barrel and is made of polyurethane, the structure is firmer, the heat preservation effect is better, vent holes 6 penetrate through the inside and outside of the center of the top end of the heat preservation barrel 1, a water adding pipe 8 penetrates through the inside and outside of the right side of the center of the top end of the heat preservation barrel 1, the top end of the water adding pipe 8 is connected with a water adding port 7, a heat exchange integration device 3 is arranged on the upper side of the inner wall of the left end of the heat preservation barrel 1, a partition plate 4 is arranged on the lower side of the heat exchange integration device 3, connecting holes penetrate through the upper and lower parts of the center of the upper end of the partition plate 4, the partition plate 4 divides the inside of the heat preservation barrel 1 into an upper layer and a lower layer, the upper layer and a lower layer of the heat preservation barrel 1 are communicated through the connecting holes, the layered water temperature is more sufficient, water mixing is prevented, hot water can be better conveyed to an upper layer, a solar integration device 5 is arranged on the lower side of the left end of a heat-preserving barrel 1, a heat pump device 11 is arranged on the right end of the heat-preserving barrel 1, a heat exchange integration 10 is arranged on the right side of the heat pump device 11, a drying room 9 is arranged on the right side of the heat-preserving barrel 1, drain pipes 12 penetrate through the inside and the outside of the lower end of the heat-preserving barrel 1, the heat exchange integration device 3 comprises a medium inlet 13, a heat exchange pipe 14, heat exchange fins 15 and a medium outlet 16, a medium inlet 13 penetrates through the inside and the outside of the upper side of the inner wall of the left end of the heat-preserving barrel 1, the heat exchange pipe 14 is connected with the heat exchange tubes 14 at the outer ends thereof, the medium inlet 13 conveys a heat medium into the heat exchange pipe 14, the heat exchange tubes 14 and the heat exchange fins 15 heat the water on the upper layer in the heat-preserving barrel 1 by heat of the heat medium, the medium outlet 16 discharges the cooled medium, and the left end of the medium inlet 13 is connected with a start-stop control unit and can intelligently control the start and stop of the inflow of the heat medium, so that the heat can be quickly dissipated, the heating can be quickly performed, and the temperature can be well controlled.
Example two
Referring to fig. 1, fig. 2, fig. 3 and fig. 4, the present invention provides a technical solution: an energy transfer heat preservation water tank in a dried noodle drying system, a solar energy integration device 5 comprises a hot water outlet pipe 17, a solar panel 18, a circulating pump 19 and a cold water inlet pipe 20, the hot water outlet pipe 17 penetrates through the inside and outside of the lower side of the left end of a heat preservation barrel 1, the lower end of the hot water outlet pipe 17 is connected with the solar panel 18, the left side of the lower end of the solar panel 18 is connected with the cold water inlet pipe 20, the circulating pump 19 is arranged in the middle of the cold water inlet pipe 20, a heat pump device 11 comprises an upper layer water outlet pipe 21, a heating pump 22, a water inlet pump 23 and a lower layer water inlet pipe 24, the upper layer water outlet pipe 21 penetrates through the inside and outside of the upper side of the right end of the heat preservation barrel 1, the heating pump 22 is connected with the right end of the upper layer water outlet pipe 21, the lower side of the left end of the heating pump 22 is connected with the lower layer water inlet pipe 24, the water inlet pump 23 is arranged in the middle of the lower layer water inlet pipe 20, the lowest layer cold water in the heat preservation barrel 1 is conveyed to the inside of the solar panel 18 for heating through the circulating pump 19, solar panel 18 is gone into 1 insidely of heat-preserving container through hot water exit tube 17 log raft after heating, 19 inside being provided with of circulating pump opens and stops the control unit, open and stop the opening and stop of control unit according to difference in temperature control circulating pump 19, the heating is more environmental protection, can heat repeatedly, can better control heating temperature, lower floor's oral siphon 24 carries the inside lower floor's water of heat-preserving container 1 through intake pump 23 to heat pump 22 inside, heat pump 22 is gone into 1 inside upper strata of heat-preserving container through the log raft after upper outlet pipe 21 will heat, intake pump 23 is inside to be provided with to open and stop the control unit and can carry out intelligence to intake pump 23 and open and stop control, more timely heating can be realized, more timely supply with hot water, better control is used with other heating device's cooperation.
The utility model discloses a theory of operation and use flow: after the solar energy heat-preserving barrel is installed, the connection state of pipelines is checked, the interior of the heat-preserving barrel 1 is added to a specified position through the water filling port 7 and the water filling pipe 8, the equipment is electrified to be operated, water is heated to a preset temperature through the solar energy integration device 5, circulating water is conveyed to the interior of the solar energy panel 18 through the circulating pump 19 to be heated, and then the circulating water flows back to the lower layer in the heat-preserving barrel 1 after being heated, the heating mode is more environment-friendly, the cost is lower, the production cost is reduced, the intelligent starting and stopping unit stops the operation of the solar energy integration device 5 after the water is heated to the preset temperature, the hot water on the upper layer in the heat-preserving barrel 1 is conveyed to the interior of the drying room 9 through the heat exchange integration 10 in the production process, the heat is dissipated into the drying room 9, the cooled water flows back to the lower layer in the heat-preserving barrel 1, the solar energy integration device 5 can operate again when the water temperature of the lower layer in the heat-preserving barrel 1 is reduced, when the hot water supply is insufficient or the sunlight is poor, the heat pump device 11 can be started under the control of the intelligent start-stop unit, the circulating water can be continuously heated under the condition of insufficient supply or poor sunlight, the heated hot water can be directly fed into the upper layer area in the heat-insulating barrel 1, the condition that the solar panel 18 is insufficiently heated is compensated, the production is ensured, meanwhile, the heated circulating water is directly fed into the upper layer area in the heat-insulating barrel 1, the hot water can be more quickly supplied to the drying room 9, the hot water supply efficiency is improved, the production efficiency is ensured, when the hot water consumption is large or the medium heating cost is lower, the intelligent start-stop unit can start the heat exchange integrated device 3, the heat medium can quickly heat the upper layer water in the heat-insulating barrel 1 through the heat exchange tubes 14 and the heat exchange fins 15, the upper layer water in the heat-insulating barrel 1 can be quickly heated to the preset temperature, and after the upper layer water is heated to the preset temperature, the intelligent start-stop unit can close the inflow of a heat medium, hot water supply required by production is guaranteed, heating efficiency is improved, normal production is guaranteed, production efficiency is guaranteed, and under the guarantee of multilayer heating, sufficient hot water is continuously supplied by energy sources to guarantee normal production.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides an energy transfer holding water box among vermicelli drying system, includes heat-preserving container (1) and gap (2), its characterized in that: an overflow port (2) penetrates through the upper side of the left end of the heat-insulating barrel (1) from inside to outside, vent holes (6) penetrate through the center of the top end of the heat-insulating barrel (1) from inside to outside, a water feeding pipe (8) penetrates through the right side of the center of the top end of the heat-insulating barrel (1) from inside to outside, the top end of the water feeding pipe (8) is connected with a water feeding port (7), a heat exchange integration device (3) is arranged on the upper side of the inner wall of the left end of the heat-insulating barrel (1), a partition plate (4) is arranged on the lower side of the heat exchange integration device (3), a solar integration device (5) is arranged on the lower side of the left end of the heat-insulating barrel (1), a heat pump device (11) is arranged at the right end of the heat-insulating barrel (1), a heat exchange integration (10) is arranged on the right side of the heat pump device (11), a drying room (9) is arranged on the right side of the heat-insulating barrel (1), and drain pipes (12) penetrate through the inside and outside the lower end of the heat-insulating barrel (1), the heat exchange integrated device (3) comprises a medium inlet (13), a heat exchange tube (14), heat exchange fins (15) and a medium outlet (16), the medium inlet (13) is arranged inside and outside the upper side of the inner wall at the left end of the heat-insulating barrel (1), the heat exchange tube (14) is connected to the right end of the medium inlet (13), the plurality of heat exchange fins (15) are connected to the outer end of the heat exchange tube (14), the medium outlet (16) is connected to the lower side at the left end of the heat exchange tube (14), the solar integrated device (5) comprises a hot water outlet tube (17), a solar panel (18), a circulating pump (19) and a cold water inlet tube (20), the hot water outlet tube (17) is arranged inside and outside the lower side at the left end of the heat-insulating barrel (1), the solar panel (18) is connected to the lower end of the solar panel (18), the cold water inlet tube (20) is connected to the left side of the solar panel (18), and the circulating pump (19) is arranged in the middle of the cold water inlet tube (20), the heat pump device (11) comprises an upper-layer water outlet pipe (21), a heating pump (22), a water inlet pump (23) and a lower-layer water inlet pipe (24), the upper-layer water outlet pipe (21) penetrates through the upper side and the lower side of the right end of the heat-insulating barrel (1), the right end of the upper-layer water outlet pipe (21) is connected with the heating pump (22), the lower side of the left end of the heating pump (22) is connected with the lower-layer water inlet pipe (24), and the water inlet pump (23) is arranged in the middle of the lower-layer water inlet pipe (24).
2. The energy transferring and heat preserving water tank in the fine dried noodle drying system according to claim 1, characterized in that: the heat-insulating barrel (1) consists of an inner barrel and an outer barrel, a heat-insulating layer is arranged between the inner barrel and the outer barrel, and the heat-insulating layer is made of polyurethane.
3. The energy transferring and heat preserving water tank in the fine dried noodle drying system according to claim 1, characterized in that: the heat-preserving container is characterized in that a connecting hole penetrates through the center of the upper end of the partition plate (4) from top to bottom, the partition plate (4) divides the interior of the heat-preserving container (1) into an upper layer and a lower layer, and the upper layer and the lower layer of the heat-preserving container (1) are communicated through the connecting hole.
4. The energy transferring and heat preserving water tank in the fine dried noodle drying system according to claim 1, characterized in that: inside heat exchange tube (14) will be carried with hot medium to medium entry (13), heat exchange tube (14) and heat exchanger fin (15) heat the water heating of the inside upper strata of heat-insulating bucket (1) through the heat of radiating hot medium, medium export (16) are discharged the refrigerated medium, medium entry (13) left end is connected with and stops the control unit and can intelligent control hot medium inflow and stop.
5. The energy transferring and heat preserving water tank in the fine dried noodle drying system according to claim 1, characterized in that: the solar energy water heater is characterized in that the cold water inlet pipe (20) conveys the cold water at the lowest layer inside the heat-insulating barrel (1) to the inside of the solar panel (18) through the circulating pump (19) to be heated, the solar panel (18) discharges the heated water into the inside of the heat-insulating barrel (1) through the hot water outlet pipe (17), the inside of the circulating pump (19) is provided with a start-stop control unit, and the start-stop control unit controls the start and stop of the circulating pump (19) according to the temperature difference.
6. The energy transferring and heat preserving water tank in the fine dried noodle drying system according to claim 1, characterized in that: lower floor's oral siphon (24) are carried the inside lower floor water of heat-preserving container (1) through intake pump (23) and are heated inside heating pump (22), the inside upper strata of heat-preserving container (1) is gone into to the log raft after heating through upper outlet pipe (21) in heating pump (22), intake pump (23) inside is provided with to open and stops the control unit and can the pattern data analysis and open and stop control to intake pump (23) intelligence.
CN202221200912.XU 2022-05-18 2022-05-18 Energy transfer heat preservation water tank in vermicelli drying system Active CN217383561U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202221200912.XU CN217383561U (en) 2022-05-18 2022-05-18 Energy transfer heat preservation water tank in vermicelli drying system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202221200912.XU CN217383561U (en) 2022-05-18 2022-05-18 Energy transfer heat preservation water tank in vermicelli drying system

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Publication Number Publication Date
CN217383561U true CN217383561U (en) 2022-09-06

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ID=83087549

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Application Number Title Priority Date Filing Date
CN202221200912.XU Active CN217383561U (en) 2022-05-18 2022-05-18 Energy transfer heat preservation water tank in vermicelli drying system

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