CN219531401U - Energy-efficient horizontal cold dryer - Google Patents

Abstract

The utility model relates to the technical field of cold and dry machines, in particular to a high-efficiency energy-saving horizontal cold and dry machine which comprises a refrigerating chamber used for cooling compressed air, wherein a drying chamber with a sealing door at the top is arranged above the refrigerating chamber, one side of the refrigerating chamber is provided with a refrigerating system, one side of the refrigerating chamber is provided with an air circulation system used for circulating air entering the cold and dry machine, the inside of the drying chamber is provided with a placing net used for placing articles, two sides of the placing net are fixedly connected with handles, the air circulation system comprises an air pump, the input end of the air pump is provided with an exhaust pipe, the output end of the air pump is provided with an air inlet pipe, the input end of the exhaust pipe is communicated with the drying chamber, the output end of the air inlet pipe is communicated with the refrigerating chamber, and the air circulation system can be used for air circulation inside the cold and dry machine and can be used for water generated in the drying process. Realizing the effect of high efficiency and energy saving.

Description

Energy-efficient horizontal cold dryer

Technical Field

The utility model relates to the technical field of cold drying machines, in particular to a high-efficiency energy-saving horizontal cold drying machine.

Background

Tea tends to be diversified more and more, flower tea is popular nowadays, when flower tea is processed, flower tea needs to be dried, the existing drying mode is divided into hot drying and cold drying, as flower of flower tea needs to keep the internal structure undamaged, the flower is dried in a cold drying mode, the existing cold dryer works on the principle that air is cooled by using a refrigerating system, moisture in the air is condensed into water drops, the water drops become dry cold air, and the surface of the flower is dried by using the dry cold air, so that the existing technology has the problems that; in the existing process of drying flowers by dry and cold air, the air cannot be recycled, so that the moisture on the surfaces of the flowers is taken away, but the temperature of the air is still lower, direct discharge is wasted, the external air is extracted newly to refrigerate the wasted electric quantity, the refrigeration speed is low, meanwhile, the existing air cannot fully contact with the evaporator tube in the refrigeration process, the moisture in the air is not easy to remove, the removed water cannot be utilized, and waste is caused. It is therefore highly desirable to design an efficient and energy-efficient horizontal type dryer to solve the above problems.

Disclosure of Invention

In view of the above problems, an object of the present utility model is to: the horizontal type air dryer is efficient and energy-saving, can recycle air in the air dryer, and can utilize water generated in a drying process. Realizing the effect of high efficiency and energy saving.

In order to achieve the above purpose, the utility model adopts the technical scheme that: the utility model provides a horizontal cold dry machine of energy-efficient, is including being used for carrying out refrigerated refrigerating chamber to compressed air, refrigerating chamber's top is provided with the drying chamber that the top has the sealing door, one side of refrigerating chamber is provided with refrigerating system, one side of refrigerating chamber is provided with the air circulation system who is used for the inside advance type gas circulation of cold dry machine, the inside of drying chamber is provided with the net of placing that is used for placing article, the both sides fixedly connected with handle of placing the net, air circulation system includes the air pump, the input of air pump is provided with the blast pipe, the output of air pump is provided with the intake pipe, the input and the drying chamber intercommunication of blast pipe, the output and the refrigerating chamber intercommunication of intake pipe.

The beneficial effects of the utility model are as follows: the blast pipe and the intake pipe of air pump can realize that the inside air of cold press circulates between drying chamber and refrigeration room, and abundant utilization cold residual temperature of inflating refrigerates once more, compares and refrigerates in the air from the outside again and saves energy.

In order to enable the refrigeration system to facilitate removal of water from the cool air.

As a further improvement of the above technical scheme: the refrigerating system comprises a refrigerating compressor, a condenser is arranged at the output end of the refrigerating compressor, a capillary tube is arranged at the output end of the condenser, an evaporating pipe is arranged at the output end of the capillary tube, the output end of the evaporating pipe is connected with the input end of the refrigerating compressor, the evaporating pipe is positioned in the refrigerating chamber, a conical water storage chamber is arranged at the bottom of the refrigerating chamber, an air inlet pipe is positioned below the evaporating pipe, and a cooling chamber is arranged outside the condenser.

The beneficial effects of this improvement are: the air and the evaporating pipe are fully contacted and then refrigerated, and after the moisture in the air is liquefied, the liquefied water can be conveniently collected.

In order to enable the air to be in full contact with the condenser, the condensed water is convenient to drop into the water storage chamber.

As a further improvement of the above technical scheme: the outside adhesion of evaporating pipe has a plurality of slant baffles that are parallel to each other, the upper portion of slant baffle overlaps with adjacent slant baffle lower part in the vertical direction.

The beneficial effects of this improvement are: the contact area with the air can be increased by a plurality of baffles that are parallel to each other, realizes the refrigeration, and is better to the dewatering effect of air.

To further increase the water removal effect:

as a further improvement of the above technical scheme: the top of the inclined baffle plate is integrally formed with a flat plate part.

The beneficial effects of this improvement are: the flat plate part is arranged, so that the contact area of air is further increased, and meanwhile, the liquefied water is convenient to drop into the water storage chamber.

In order to allow water in the water storage chamber to be utilized.

As a further improvement of the above technical scheme: the bottom of the water storage chamber is provided with a valve, the output end of the valve is provided with a water inlet pipe, the output end of the water inlet pipe is provided with a water pump, the output end society of the water pump is provided with a drain pipe, and the output end of the drain pipe is communicated with the cooling chamber.

The improved beneficial effects are that; the water in the water storage chamber can be pumped into the cooling chamber through the water pump, the water inlet pipe and the water outlet pipe, so that the effect of cooling the condenser is achieved.

In order to allow the condenser to still dissipate heat when there is insufficient water in the water reservoir.

As a further improvement of the above technical scheme: the cooling device is characterized in that a wind scooper is fixedly connected above the cooling chamber, a fan is arranged in the wind scooper, and an air outlet is formed in one side of the cooling chamber.

The beneficial effects of this improvement are: the condenser can still be cooled by the fan.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a front view of the present utility model.

Fig. 3 is a side view of the present utility model.

FIG. 4 is a schematic cross-sectional view of the utility model at B-B in FIG. 3.

FIG. 5 is a schematic cross-sectional view of the utility model at C-C in FIG. 3.

Fig. 6 is an enlarged schematic view of the present utility model at a in fig. 4.

In the figure: 1. a refrigerating chamber; 2. a drying chamber; 3. a refrigeration system; 301. a compressor; 302. a condenser; 303. a capillary tube; 304. an evaporation tube; 4. an air circulation system; 401. an air pump; 402. an exhaust pipe; 403. an air inlet pipe; 5. sealing the door; 6. placing a net; 601. a handle; 7. an inclined baffle; 701. a flat plate portion; 8. a water storage chamber; 9. a valve; 10. a water inlet pipe; 11. a water pump; 12. a drain pipe; 13. a cooling chamber; 14. a fan housing; 15. an air outlet; 16. a blower.

Detailed Description

In order that those skilled in the art may better understand the technical solutions of the present utility model, the following detailed description of the present utility model with reference to the accompanying drawings is provided for exemplary and explanatory purposes only and should not be construed as limiting the scope of the present utility model.

Example 1:

as shown in fig. 1 to 6, a horizontal type efficient energy-saving cooling dryer comprises a cooling chamber 1 for cooling compressed air, a drying chamber 2 with a sealing door 5 at the top is arranged above the cooling chamber 1, a cooling system 3 is arranged on one side of the cooling chamber 1, an air circulation system 4 for circulating air entering the inside of the cooling dryer is arranged on one side of the cooling chamber 1, a placing net 6 for placing articles is arranged in the drying chamber 2, handles are fixedly connected to two sides of the placing net 6, the air circulation system 4 comprises an air pump 401, an air exhaust pipe 402 is arranged at the input end of the air pump 401, an air inlet pipe 403 is arranged at the output end of the air pump 401, the input end of the air exhaust pipe 402 is communicated with the drying chamber 2, and the output end of the air inlet pipe 403 is communicated with the cooling chamber 1.

Example 2:

as shown in fig. 1 to 6, as a further optimization of the above embodiment, a horizontal type air dryer with high efficiency and energy saving comprises a refrigerating chamber 1 for cooling compressed air, wherein a drying chamber 2 with a sealing door 5 at the top is arranged above the refrigerating chamber 1, one side of the refrigerating chamber 1 is provided with a refrigerating system 3, one side of the refrigerating chamber 1 is provided with an air circulation system 4 for circulating inlet air in the air dryer, the inside of the drying chamber 2 is provided with a placing net 6 for placing articles, two sides of the placing net 6 are fixedly connected with handles, the air circulation system 4 comprises an air pump 401, an input end of the air pump 401 is provided with an exhaust pipe 402, an output end of the air pump 401 is provided with an air inlet pipe 403, an input end of the exhaust pipe 402 is communicated with the drying chamber 2, an output end of the air inlet pipe 403 is communicated with the refrigerating chamber 1, the refrigerating system comprises a refrigerating compressor 301, an output end of the refrigerating compressor 301 is provided with a condenser 302, an output end of the condenser 302 is provided with a capillary tube 303, an output end of the condenser 304 is provided with an evaporator tube 304, an output end of the evaporator tube 403 is provided with an evaporator tube 301, and an input end of the evaporator tube 3 is provided with an evaporator tube 1, and is provided with an evaporator tube 3, and an evaporator tube is provided with an evaporator tube 3.

Example 3:

as shown in fig. 1 to 6, as a further optimization of the above embodiment, a high-efficiency energy-saving horizontal type cold dryer comprises a refrigerating chamber 1 for cooling compressed air, a drying chamber 2 with a sealing door 5 at the top is arranged above the refrigerating chamber 1, a refrigerating system 3 is arranged at one side of the refrigerating chamber 1, an air circulation system 4 for circulating inlet air in the cold dryer is arranged at one side of the refrigerating chamber 1, a placing net 6 for placing articles is arranged in the drying chamber 2, handles are fixedly connected to two sides of the placing net 6, the air circulation system 4 comprises an air pump 401, an exhaust pipe 402 is arranged at the input end of the air pump 401, an air inlet pipe 403 is arranged at the output end of the air pump 401, the input end of the exhaust pipe 402 is communicated with the drying chamber 2, the output end of the air inlet pipe 403 is communicated with the refrigerating chamber 1, the refrigerating system comprises a refrigerating compressor 301, a condenser 302 is arranged at the output end of the refrigerating compressor 301, a capillary 303 is arranged at the output end of the condenser 302, an evaporation pipe 304 is arranged at the output end of the capillary 303, the output end of the evaporation pipe 304 is connected with the input end of the refrigerating compressor 301, the evaporation pipe 304 is positioned in the refrigerating chamber 1, a conical water storage chamber 8 is arranged at the bottom of the refrigerating chamber 1, the air inlet pipe 403 is positioned below the evaporation pipe 304, a cooling chamber 13 is arranged outside the condenser, a plurality of inclined baffles 7 which are parallel to each other are adhered to the outside of the evaporation pipe 304, and the upper parts of the inclined baffles 7 are overlapped with the lower parts of the adjacent inclined baffles 7 in the vertical direction.

Example 4:

as shown in fig. 1 to 6, as a further optimization of the above embodiment, a high-efficiency and energy-saving horizontal type dryer comprises a refrigerating chamber 1 for cooling compressed air, a drying chamber 2 with a sealing door 5 at the top is arranged above the refrigerating chamber 1, a refrigerating system 3 is arranged at one side of the refrigerating chamber 1, an air circulation system 4 for circulating inlet air in the dryer is arranged at one side of the refrigerating chamber 1, a placing net 6 for placing articles is arranged in the drying chamber 2, handles are fixedly connected to two sides of the placing net 6, the air circulation system 4 comprises an air pump 401, an exhaust pipe 402 is arranged at the input end of the air pump 401, an air inlet pipe 403 is arranged at the output end of the air pump 401, the input end of the exhaust pipe 402 is communicated with the drying chamber 2, the output end of the air inlet pipe 403 is communicated with the refrigerating chamber 1, the refrigerating system comprises a refrigerating compressor 301, a condenser 302 is arranged at the output end of the refrigerating compressor 301, a capillary 303 is arranged at the output end of the condenser 302, an evaporating pipe 304 is arranged at the output end of the capillary 303, the output end of the evaporating pipe 304 is connected with the input end of the refrigerating compressor 301, the evaporating pipe 304 is positioned in the refrigerating chamber 1, a conical water storage chamber 8 is arranged at the bottom of the refrigerating chamber 1, an air inlet pipe 403 is positioned below the evaporating pipe 304, a cooling chamber 13 is arranged outside the condenser, a plurality of oblique baffles 7 parallel to each other are adhered to the outside of the evaporating pipe 304, the upper parts of the oblique baffles 7 are overlapped with the lower parts of the adjacent oblique baffles 7 in the vertical direction, and a flat plate part 701 is integrally formed at the top of the oblique baffles 7.

Example 5:

as shown in fig. 1 to 6, as a further optimization of the above embodiment, a horizontal type air dryer with high efficiency and energy saving is provided, which comprises a refrigerating chamber 1 for cooling compressed air, a drying chamber 2 with a sealing door 5 at the top is arranged above the refrigerating chamber 1, one side of the refrigerating chamber 1 is provided with a refrigerating system 3, one side of the refrigerating chamber 1 is provided with an air circulation system 4 for circulating air entering the inside of the air dryer, the inside of the drying chamber 2 is provided with a placing net 6 for placing articles, two sides of the placing net 6 are fixedly connected with handles, the air circulation system 4 comprises an air pump 401, an input end of the air pump 401 is provided with an exhaust pipe 402, an output end of the air pump 401 is provided with an air inlet pipe 403, an input end of the exhaust pipe 402 is communicated with the drying chamber 2, an output end of the air inlet pipe 403 is communicated with the refrigerating chamber 1, the refrigerating system comprises a refrigerating compressor 301, an output end of the refrigerating compressor 301 is provided with a condenser 302, an output end of the condenser 302 is provided with a capillary tube 303, an output end of the condenser 302 is provided with an output pipe 304, an output end of the evaporator pipe 304 is provided with a capillary tube 304 is provided with a water storage pipe 12, an output end of the evaporator chamber 9 is provided with a water storage pipe 11 is provided with an output end of the air pump 3, an output pipe 11 is provided with a water storage pipe 11 is provided with a water inlet pipe 13, a water inlet pipe 13 is provided with a water inlet pipe 13, and a water is provided with a water outlet pipe 13 is provided with a water inlet pipe 3.

Example 6:

as shown in fig. 1 to 6, a horizontal type efficient energy-saving cold dryer comprises a refrigerating chamber 1 for cooling compressed air, a drying chamber 2 with a sealing door 5 at the top is arranged above the refrigerating chamber 1, a refrigerating system 3 is arranged on one side of the refrigerating chamber 1, an air circulation system 4 for circulating inlet air in the cold dryer is arranged on one side of the refrigerating chamber 1, a placing net 6 for placing articles is arranged in the drying chamber 2, handles are fixedly connected to two sides of the placing net 6, the air circulation system 4 comprises an air pump 401, an exhaust pipe 402 is arranged at the input end of the air pump 401, an air inlet pipe 403 is arranged at the output end of the air pump 401, the input end of the exhaust pipe 402 is communicated with the drying chamber 2, the output end of the air inlet pipe 403 is communicated with the refrigerating chamber 1, the refrigerating system comprises a refrigerating compressor 301, the output end of the refrigeration compressor 301 is provided with a condenser 302, the output end of the condenser 302 is provided with a capillary 303, the output end of the capillary 303 is provided with an evaporation pipe 304, the output end of the evaporation pipe 304 is connected with the input end of the refrigeration compressor 301, the evaporation pipe 304 is positioned in the refrigeration chamber 1, the bottom of the refrigeration chamber 1 is provided with a conical water storage chamber 8, the air inlet pipe 403 is positioned below the evaporation pipe 304, the outside of the condenser is provided with a cooling chamber 13, the bottom of the water storage chamber 8 is provided with a valve 9, the output end of the valve 9 is provided with a water inlet pipe 10, the output end of the water inlet pipe 10 is provided with a water pump 11, the output end society of the water pump 11 is provided with a water outlet pipe 12, the output end of the water outlet pipe 12 is communicated with the cooling chamber 13, the upper part of the cooling chamber 13 is fixedly connected with a wind scooper 14, the inside of the wind scooper 14 is provided with a fan 16, and one side of the cooling chamber 13 is provided with an air outlet 15.

The working principle of the utility model is as follows: the refrigeration compressor 301 and the air pump 401 are started, the refrigeration compressor 301 compresses the refrigerant, the refrigerant is compressed into a high-temperature high-pressure gas state, the refrigerant enters the condenser, the refrigerant in the condenser dissipates heat to form a high-pressure liquid refrigerant, the high-pressure liquid refrigerant is subjected to interception and depressurization through the capillary 303, the high-pressure liquid refrigerant flows into the evaporator to absorb heat due to the gas state formed by the sudden drop of pressure, the inside of the refrigeration chamber 1 is cooled, then the gaseous refrigerant enters the refrigeration compressor 301 again to circulate, the air pump 401 pumps the air in the drying chamber 2, the air enters the refrigeration chamber 1 through the exhaust pipe 402 and the air inlet pipe 403, the air in the refrigeration chamber 1 is cooled, the moisture in the air condenses, the air falls into the water storage chamber 8, the dried cold air enters the drying chamber 2 to dry the flowers on the placing net 6, the handle 601 is arranged on the upper side of the placing net 6, the air is pumped into the inside of the refrigeration chamber 1 again to cool and remove water, the water produced in the water storage chamber 8 can be pumped into the cooling chamber 13 by the water pump 11 to cool the condenser, and the water is utilized.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. The foregoing is merely illustrative of the preferred embodiments of the utility model, and it is noted that there is virtually no limit to the specific structure which may be imposed by those skilled in the art without departing from the spirit of the utility model, and that modifications, adaptations, or variations of the foregoing features may be combined in a suitable manner; such modifications, variations and combinations, or the direct application of the inventive concepts and aspects to other applications without modification, are contemplated as falling within the scope of the present utility model.

Claims (6)

1. The utility model provides a horizontal cold dryer of high-efficient energy-conservation, includes refrigerating chamber (1) that is used for carrying out the cooling to compressed air, the top of refrigerating chamber (1) is provided with drying chamber (2) that has sealing door (5) in the top, one side of refrigerating chamber (1) is provided with refrigerating system (3), its characterized in that; one side of refrigerating chamber (1) is provided with and is used for entering type gas circulation's air circulation system (4) to cold dry machine inside, the inside of drying chamber (2) is provided with places net (6) that are used for placing article, place the both sides fixedly connected with handle of net (6), air circulation system (4) include air pump (401), the input of air pump (401) is provided with blast pipe (402), the output of air pump (401) is provided with intake pipe (403), the input and the drying chamber (2) intercommunication of blast pipe (402), the output and the refrigerating chamber (1) intercommunication of intake pipe (403).

2. The energy-efficient horizontal type cold dryer according to claim 1, wherein: refrigerating system (3) are including refrigerating compressor (301), refrigerating compressor (301)'s output is provided with condenser (302), condenser (302)'s output is provided with capillary (303), capillary (303)'s output is provided with evaporating pipe (304), evaporating pipe (304)'s output is connected with refrigerating compressor (301)'s input, evaporating pipe (304) are in refrigerating chamber (1)'s inside, refrigerating chamber (1)'s bottom is provided with water storage room (8) of cone mouth shape, intake pipe (403) are in evaporating pipe (304)'s below, condenser (302) outside is provided with cooling chamber (13).

3. The energy-efficient horizontal type cold dryer according to claim 2, wherein: the outside of evaporating pipe (304) is adhered with a plurality of slant baffles (7) that are parallel to each other, the upper portion of slant baffle (7) and adjacent slant baffle (7) lower part coincide in the vertical direction.

4. A high efficiency energy saving horizontal cold dryer as set forth in claim 3 wherein: the top of the inclined baffle (7) is integrally formed with a flat plate part (701).

5. The energy-efficient horizontal type cold dryer according to claim 2, wherein: the bottom of retaining room (8) is provided with valve (9), the output of valve (9) is provided with inlet tube (10), the output of inlet tube (10) is provided with water pump (11), the output society of water pump (11) has drain pipe (12), the output and the cooling chamber (13) of drain pipe (12) communicate.

6. The energy-efficient horizontal type cold dryer according to claim 5, wherein: the cooling device is characterized in that a wind scooper (14) is fixedly connected above the cooling chamber (13), a fan (16) is arranged inside the wind scooper (14), and an air outlet (15) is formed in one side of the cooling chamber (13).