CN112414053A - Drying device with cooling mechanism for textile machinery and operation method thereof - Google Patents

Abstract

The invention discloses a drying device with a cooling mechanism for textile machinery and an operation method of the drying device, and belongs to the technical field of drying devices. Multi-level drying at different temperatures is carried out by adopting high-temperature drying equipment and a low-temperature cloth drying method, gas volatilized from residual dye in a drying cavity is discharged, the brightness of the color of the cloth is ensured, and the damage of the cloth caused by high temperature is reduced; the drying speed and the drying uniformity are increased, and the occupied volume is reduced.

Description

Drying device with cooling mechanism for textile machinery and operation method thereof

Technical Field

The invention relates to the technical field of drying devices, in particular to a drying device with a cooling mechanism for textile machinery and an operation method thereof.

Background

The original textile concept is a general name taken from spinning and weaving, but with the continuous development and perfection of a textile knowledge system and a subject system, particularly after non-woven textile materials and three-dimensional composite weaving and other technologies are produced, the current textile is not only the traditional hand-made spinning and weaving, but also comprises non-woven fabric technology, modern three-dimensional weaving technology, modern electrostatic nano-net forming technology and other produced textiles for clothing, industry and decoration, so the modern textile refers to a multi-scale structure processing technology of fibers or fiber aggregates, ancient textile and printing and dyeing technology in China has a very long history, the current textile cloth drying device adopts high temperature to dry the cloth, not only can reduce the brightness of the cloth color, but also can damage the cloth, and as the drying space is small, the amount of the cloth capable of being dried and accommodated is small, the drying efficiency is low, the drying uniformity is low.

Disclosure of Invention

The invention aims to provide a drying device with a cooling mechanism for textile machinery and an operation method thereof, which adopt high-temperature drying equipment and a method for drying cloth at low temperature to carry out multi-layer drying at different temperatures, wherein the high-temperature drying is used for sterilizing and disinfecting, and gas volatilized from residual dye in a drying cavity is discharged, so that the brightness of the color of the cloth is ensured by low-temperature drying, and the damage of the cloth caused by high temperature is reduced; the drying support which can rotate and be accommodated is adopted as a structure for hanging the cloth, the drying speed and the drying uniformity are increased, and the drying support can be folded when the cloth is not dried, so that the occupied volume is reduced, and the problem in the background technology is solved.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a weaving machinery is with drying device who has cooling mechanism, includes drying chamber, stoving support, stoving roof, stoving bottom plate, cooling system and controller, the inside of drying chamber is provided with the stoving support, and the top fixedly connected with stoving roof of drying chamber, and bottom fixedly connected with stoving bottom plate, stoving roof and stoving bottom plate all are circularly, and the curb plate is the annular plate body, forms columniform stoving chamber between the three, be provided with cooling system on the stoving roof, cooling system is connected with the controller through radio signal.

Further, the drying chamber includes the curb plate, inclines door, gas vent and support column, the four peripheral angle departments of drying chamber all are provided with the support column, through curb plate interconnect between the adjacent support column, seted up on the curb plate of drying chamber front end and incline the door, and the edge department of every curb plate lower extreme has all seted up the gas vent, and curb plate, stoving roof and stoving bottom plate all are the rectangle, form the stoving chamber of rectangle between the three.

Further, the drying support comprises a main rotating motor, a rotating base plate, a rotating main shaft and hanging mechanisms, wherein the main rotating motor is installed on the drying base plate, a motor shaft of the main rotating motor is connected with the rotating base plate through a coupler, the rotating main shaft is fixedly connected to the upper end of the rotating base plate, and four hanging mechanisms are arranged on the periphery of the rotating main shaft and distributed in an annular shape.

Further, hang mechanism including installation backplate, linking panel, horizontal pole subassembly, side ear, rotatory countershaft and adjusting bolt, install the backplate and link up the horizontal pole subassembly of arranging through bolt fixedly connected with a plurality of equidistant between the panel, the equal fixedly connected with side ear of upper end and the lower extreme of installation backplate, two it has rotatory countershaft to connect soon through adjusting bolt between the side ear.

Further, the rotating spindle comprises a barrel body, a nozzle and a pipeline interface, the barrel body is provided with a cavity, the cavity is communicated with the nozzle on the side wall of the barrel body, the pipeline interface is arranged on the upper end face of the barrel body, and the pipeline interface is communicated with the cavity inside the barrel body.

Further, the horizontal pole subassembly includes the horizontal pole body of rod, horizontal pole connecting axle, drive gear, horizontal pole base, drive chain and driving motor, all through bolt fixedly connected with horizontal pole base on the lateral wall of installation backplate and linking panel, the both ends of the horizontal pole body of rod all are provided with the horizontal pole connecting axle to through horizontal pole connecting axle respectively swivelling joint install horizontal pole base on the backplate and link up the horizontal pole base on the panel, fixedly connected with drive gear on the horizontal pole connecting axle, it is a plurality of drive gear on the horizontal pole subassembly all is through drive chain interconnect, the horizontal pole connecting axle of one of them horizontal pole subassembly is connected with driving motor.

Furthermore, all seted up the regulation screw on the up end of rotatory countershaft and the terminal surface down, rotatory countershaft has connect adjusting bolt through adjusting the screw soon, adjusting bolt welds on the side ear.

Further, the cooling system includes air intake, heater, refrigerator, air pump, humidity transducer and temperature sensor, the inside cavity of drying chamber communicates with each other through pipeline and air pump, the air pump has the refrigerator through the pipe connection, the refrigerator has heater through the pipe connection, the air intake has been seted up to the upper end of heater, all series connection has the valve on the pipeline of installing humidity transducer and temperature sensor air pump connection on the inner wall of curb plate, air intake department is provided with the filter screen.

Further, the humidity sensor and the temperature sensor are connected with a controller through wireless signals, and the controller is connected with a heater, a refrigerator, an air pump, a driving motor and a main rotating motor through wireless signals.

According to another aspect of the present invention, there is provided a method of operating a drying apparatus for textile machinery having a cooling mechanism, comprising the steps of:

s101: high-temperature drying, namely inputting an instruction to a controller to start a heater and an air pump, driving external air to enter a drying cavity after drying by the air pump, and filling the dried high-temperature air into the drying cavity;

s102: drying at low temperature, starting a refrigerator, introducing gas which is dried and then cooled to a certain temperature into the drying cavity, and hanging the cloth to be dried;

s103: rotating and drying, wherein a main rotating motor drives a rotating main shaft to rotate so as to accelerate drying;

s104: controlling the temperature, and adjusting the refrigerating intensity of the refrigerator after the temperature sensor detects that the temperature in the drying cavity is different from a set temperature value, so as to control the temperature of the gas entering the drying cavity;

s105: and controlling the humidity, and adjusting the heating intensity of the heater after the humidity sensor detects that the difference exists between the humidity in the drying cavity and the set humidity value, so as to control the humidity of the gas entering the drying cavity.

Compared with the prior art, the invention has the beneficial effects that: the drying device with the cooling mechanism for the textile machinery and the operation method thereof adopt high-temperature drying equipment and a low-temperature cloth drying method to carry out multi-level drying at different temperatures, wherein the high-temperature drying is used for drying, sterilizing and disinfecting, and gas volatilized from residual dye in a drying cavity is discharged, so that the color brightness of the cloth is ensured by low-temperature drying, and the damage of the cloth caused by high temperature is reduced; the drying support which can rotate and be accommodated is adopted as a structure for hanging the cloth, the accommodating capacity of the dried cloth in unit volume is increased, the drying speed and the drying uniformity are increased in a rotating mode, and the drying support can be folded when the drying is not carried out, so that the occupied volume is reduced.

Drawings

Fig. 1 is an overall structural view of a drying apparatus with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

fig. 2 is a structural view of a cooling system of a drying device with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

FIG. 3 is a bottom view of a top plate of a drying device with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

FIG. 4 is a structural view of a drying chamber of a drying apparatus with a cooling mechanism for textile machinery in a first embodiment of the present invention;

FIG. 5 is a structural diagram of a drying rack of a drying device with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

FIG. 6 is a structural view of a hanging mechanism of a drying device with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

FIG. 7 is an exploded view of a cross bar assembly of a drying apparatus with a cooling mechanism for a textile machine according to a first embodiment of the present invention;

FIG. 8 is a partial exploded view taken at A of FIG. 6 in accordance with the present invention;

fig. 9 is an overall configuration view of a drying apparatus having a cooling mechanism for a textile machine according to a second embodiment of the present invention;

FIG. 10 is a structural view of a drying chamber of a drying apparatus having a cooling mechanism for textile machinery according to a second embodiment of the present invention;

FIG. 11 is a flowchart of an operation method of the drying device with a cooling mechanism for a textile machine according to the present invention.

In the figure: 100. a drying chamber; 110. a side plate; 120. a side door; 130. an exhaust port; 140. a support pillar; 200. drying the bracket; 210. a main rotating electrical machine; 220. rotating the base plate; 230. rotating the main shaft; 231. a barrel; 232. a nozzle; 233. a pipe interface; 240. a suspension mechanism; 241. mounting a back plate; 242. joining the panels; 243. a cross bar assembly; 2431. a cross bar body; 2432. a cross bar connecting shaft; 2433. a transmission gear; 2434. a cross bar base; 2435. a drive chain; 2436. a drive motor; 244. a lateral ear; 245. rotating the counter shaft; 246. adjusting the bolt; 247. adjusting the screw hole; 300. drying the top plate; 400. drying the bottom plate; 500. a cooling system; 510. an air inlet; 520. a heater; 530. a refrigerator; 540. an air pump; 550. a humidity sensor; 560. a temperature sensor; 600. and a controller.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

Referring to fig. 1 to 4, a drying device with a cooling mechanism for textile machinery, includes a drying chamber 100, a drying support 200, a drying top plate 300, a drying bottom plate 400, a cooling system 500 and a controller 600, the drying support 200 is arranged inside the drying chamber 100, the drying top plate 300 is fixedly connected to the top of the drying chamber 100, the drying bottom plate 400 is fixedly connected to the bottom, the cooling system 500 is arranged on the drying top plate 300, and the cooling system 500 is connected with the controller 600 through a wireless signal.

Cooling system 500 includes air intake 510, heat generator 520, refrigerator 530, air pump 540, humidity sensor 550 and temperature sensor 560, the inside cavity of drying chamber 100 communicates with air pump 540 through the pipeline each other, air pump 540 has refrigerator 530 through the pipe connection, all series connection has the valve on the pipeline that air pump 540 connects, the switch of valve is used for controlling whether gaseous circulation, refrigerator 530 has heat generator 520 through the pipe connection, air intake 510 has been seted up to the upper end of heat generator 520, air intake 510 department is provided with the filter screen, be used for filtering the dust, install humidity sensor 550 and temperature sensor 560 on the inner wall of curb plate 110, humidity sensor 550 and temperature sensor 560 have controller 600 through wireless signal connection, controller 600 has heat generator 520 through wireless signal connection, refrigerator 530, air pump 540, driving motor 2436 and main rotating electrical machines 210.

The drying chamber 100 comprises side plates 110, side doors 120, air outlets 130 and support columns 140, wherein the support columns 140 are arranged at the corners of the periphery of the drying chamber 100, the adjacent support columns 140 are connected with each other through the side plates 110, the side plates 110 at the front end of the drying chamber 100 are provided with the side doors 120, and the air outlets 130 are arranged at the corners of the lower end of each side plate 110; the side plates 110, the drying top plate 300 and the drying bottom plate 400 are all rectangular, and rectangular drying cavities are formed among the side plates, the drying top plate 300 and the drying bottom plate.

Referring to fig. 5 to 8, the drying rack 200 includes a main rotating electrical machine 210, a rotating base plate 220, a rotating spindle 230 and a hanging mechanism 240, the main rotating electrical machine 210 is installed on the drying base plate 400, a motor shaft of the main rotating electrical machine 210 is connected to the rotating base plate 220 through a coupling, the upper end of the rotating base plate 220 is fixedly connected to the rotating spindle 230, four hanging mechanisms 240 are disposed around the rotating spindle 230, and the four hanging mechanisms 240 are distributed annularly.

The suspension mechanism 240 comprises a mounting back plate 241, a connecting panel 242, a plurality of cross rod assemblies 243, side lugs 244, a rotary auxiliary shaft 245 and adjusting bolts 246, the plurality of cross rod assemblies 243 which are arranged at equal intervals are fixedly connected between the mounting back plate 241 and the connecting panel 242 through bolts, the side lugs 244 are fixedly connected to the upper end and the lower end of the mounting back plate 241, the rotary auxiliary shaft 245 is screwed between the two side lugs 244 through the adjusting bolts 246, the adjusting screw holes 247 are formed in the upper end face and the lower end face of the rotary auxiliary shaft 245, the adjusting bolts 246 are screwed to the rotary auxiliary shaft 245 through the adjusting screw holes 247, the adjusting bolts 246 are welded to the side lugs 244, the suspension mechanism 240 can be manually rotated after the adjusting bolts 246 are unscrewed, and the cross rod assemblies 243 and the rotary main shaft 230 are fixed after the; the cross bar assemblies 243 comprise cross bar bodies 2431, cross bar connecting shafts 2432, transmission gears 2433, cross bar bases 2434, transmission chains 2435 and driving motors 2436, the side walls of the installation back plate 241 and the connection panel 242 are fixedly connected with the cross bar bases 2434 through bolts, the two ends of each cross bar body 2431 are provided with the cross bar connecting shafts 2432, the cross bar bases 2434 on the installation back plate 241 and the cross bar bases 2434 on the connection panel 242 are respectively and rotatably connected through the cross bar connecting shafts 2432, the transmission gears 2433 are fixedly connected onto the cross bar connecting shafts 2432, the transmission gears 2433 on the cross bar assemblies 243 are connected with one another through the transmission chains 2435, and the cross bar connecting shaft 2432 of one of the cross bar assemblies 243 is connected with the driving motor 2436.

The rotating main shaft 230 comprises a cylinder 231, a nozzle 232 and a pipeline interface 233, the cylinder 231 is provided with a cavity, the cavity is communicated with the nozzle 232 on the side wall of the cylinder 231, the upper end face of the cylinder 231 is provided with the pipeline interface 233, and the pipeline interface 233 is communicated with the cavity inside the cylinder 231.

Referring to fig. 11, in order to better show the operation flow of the drying device with a cooling mechanism for a textile machine, the present embodiment now provides an operation method of the drying device with a cooling mechanism for a textile machine, including the following steps:

s101: high-temperature drying, namely inputting an instruction to the controller 600 to start the heater 520 and the air pump 540, driving external air to enter the drying cavity after drying by the air pump 540, and filling the dried high-temperature air into the drying cavity;

s102: drying at low temperature, starting the refrigerator 530, introducing gas which is dried and then cooled to a certain temperature into the drying cavity, and hanging the cloth to be dried; the cloth to be dried is hung manually, the cloth to be dried enters the drying cavity manually, the cloth to be dried is hung on the drying bracket 200, and then the cloth to be dried exits from the drying cavity and the side door 120 is closed;

s103: rotating and drying, wherein the main rotating motor 210 drives the rotating main shaft 230 to rotate, so as to accelerate drying;

s104: controlling the temperature, and after the temperature sensor 560 detects that the temperature in the drying cavity is different from a set temperature value, adjusting the refrigerating intensity of the refrigerator 530, so as to control the temperature of the gas entering the drying cavity;

s105: and controlling the humidity, adjusting the heating intensity of the heater 520 after the humidity sensor 550 detects that the difference exists between the humidity in the drying chamber and the set humidity value, and further controlling the humidity of the gas entering the drying chamber.

Example two

Referring to fig. 9 to 10, a drying device with a cooling mechanism for textile machinery, includes a drying chamber 100, a drying support 200, a drying top plate 300, a drying bottom plate 400, a cooling system 500 and a controller 600, the drying support 200 is arranged inside the drying chamber 100, the drying top plate 300 is fixedly connected to the top of the drying chamber 100, the drying bottom plate 400 is fixedly connected to the bottom, the cooling system 500 is arranged on the drying top plate 300, and the cooling system 500 is connected with the controller 600 through a wireless signal.

Cooling system 500 includes air intake 510, heat generator 520, refrigerator 530, air pump 540, humidity sensor 550 and temperature sensor 560, the inside cavity of drying chamber 100 communicates with air pump 540 through the pipeline each other, air pump 540 has refrigerator 530 through the pipe connection, all series connection has the valve on the pipeline that air pump 540 connects, the switch of valve is used for controlling whether gaseous circulation, refrigerator 530 has heat generator 520 through the pipe connection, air intake 510 has been seted up to the upper end of heat generator 520, air intake 510 department is provided with the filter screen, be used for filtering the dust, install humidity sensor 550 and temperature sensor 560 on the inner wall of curb plate 110, humidity sensor 550 and temperature sensor 560 have controller 600 through wireless signal connection, controller 600 has heat generator 520 through wireless signal connection, refrigerator 530, air pump 540, driving motor 2436 and main rotating electrical machines 210.

The drying chamber 100 comprises side plates 110, side doors 120, air outlets 130 and support columns 140, wherein the support columns 140 are arranged at the corners of the periphery of the drying chamber 100, the adjacent support columns 140 are connected with each other through the side plates 110, the side plates 110 at the front end of the drying chamber 100 are provided with the side doors 120, and the air outlets 130 are arranged at the corners of the lower end of each side plate 110; the drying top plate 300 and the drying bottom plate 400 are both circular, the side plate 110 is an annular plate body, and a cylindrical drying cavity is formed among the three.

Referring to fig. 5 to 8, the drying rack 200 includes a main rotating electrical machine 210, a rotating base plate 220, a rotating spindle 230 and a hanging mechanism 240, the main rotating electrical machine 210 is installed on the drying base plate 400, a motor shaft of the main rotating electrical machine 210 is connected to the rotating base plate 220 through a coupling, the upper end of the rotating base plate 220 is fixedly connected to the rotating spindle 230, four hanging mechanisms 240 are disposed around the rotating spindle 230, and the four hanging mechanisms 240 are distributed annularly.

The suspension mechanism 240 comprises a mounting back plate 241, a connecting panel 242, a plurality of cross rod assemblies 243, side lugs 244, a rotary auxiliary shaft 245 and adjusting bolts 246, the plurality of cross rod assemblies 243 which are arranged at equal intervals are fixedly connected between the mounting back plate 241 and the connecting panel 242 through bolts, the side lugs 244 are fixedly connected to the upper end and the lower end of the mounting back plate 241, the rotary auxiliary shaft 245 is screwed between the two side lugs 244 through the adjusting bolts 246, the adjusting screw holes 247 are formed in the upper end face and the lower end face of the rotary auxiliary shaft 245, the adjusting bolts 246 are screwed to the rotary auxiliary shaft 245 through the adjusting screw holes 247, the adjusting bolts 246 are welded to the side lugs 244, the suspension mechanism 240 can be manually rotated after the adjusting bolts 246 are unscrewed, and the cross rod assemblies 243 and the rotary main shaft 230 are fixed after the; the cross bar assemblies 243 comprise cross bar bodies 2431, cross bar connecting shafts 2432, transmission gears 2433, cross bar bases 2434, transmission chains 2435 and driving motors 2436, the side walls of the installation back plate 241 and the connection panel 242 are fixedly connected with the cross bar bases 2434 through bolts, the two ends of each cross bar body 2431 are provided with the cross bar connecting shafts 2432, the cross bar bases 2434 on the installation back plate 241 and the cross bar bases 2434 on the connection panel 242 are respectively and rotatably connected through the cross bar connecting shafts 2432, the transmission gears 2433 are fixedly connected onto the cross bar connecting shafts 2432, the transmission gears 2433 on the cross bar assemblies 243 are connected with one another through the transmission chains 2435, and the cross bar connecting shaft 2432 of one of the cross bar assemblies 243 is connected with the driving motor 2436.

The rotating main shaft 230 comprises a cylinder 231, a nozzle 232 and a pipeline interface 233, the cylinder 231 is provided with a cavity, the cavity is communicated with the nozzle 232 on the side wall of the cylinder 231, the upper end face of the cylinder 231 is provided with the pipeline interface 233, and the pipeline interface 233 is communicated with the cavity inside the cylinder 231.

Referring to fig. 11, in order to better show the operation flow of the drying device with a cooling mechanism for a textile machine, the present embodiment now provides an operation method of the drying device with a cooling mechanism for a textile machine, including the following steps:

s101: high-temperature drying, namely inputting an instruction to the controller 600 to start the heater 520 and the air pump 540, driving external air to enter the drying cavity after drying by the air pump 540, and filling the dried high-temperature air into the drying cavity;

s102: drying at low temperature, starting the refrigerator 530, introducing gas which is dried and then cooled to a certain temperature into the drying cavity, and hanging the cloth to be dried; the cloth to be dried is hung manually, the cloth to be dried enters the drying cavity manually, the cloth to be dried is hung on the drying bracket 200, and then the cloth to be dried exits from the drying cavity and the side door 120 is closed;

s103: rotating and drying, wherein the main rotating motor 210 drives the rotating main shaft 230 to rotate, so as to accelerate drying;

s104: controlling the temperature, and after the temperature sensor 560 detects that the temperature in the drying cavity is different from a set temperature value, adjusting the refrigerating intensity of the refrigerator 530, so as to control the temperature of the gas entering the drying cavity;

s105: and controlling the humidity, adjusting the heating intensity of the heater 520 after the humidity sensor 550 detects that the difference exists between the humidity in the drying chamber and the set humidity value, and further controlling the humidity of the gas entering the drying chamber.

In summary, the following steps: the drying device with the cooling mechanism for the textile machinery and the operation method thereof adopt high-temperature drying equipment and a low-temperature cloth drying method to carry out multi-level drying at different temperatures, wherein the high-temperature drying is used for drying, sterilizing and disinfecting, and gas volatilized from residual dye in a drying cavity is discharged, so that the color brightness of the cloth is ensured by low-temperature drying, and the damage of the cloth caused by high temperature is reduced; the drying support 200 which can rotate and be accommodated is adopted as a structure for hanging the cloth, the accommodating capacity of the dried cloth in unit volume is increased, the drying speed and the drying uniformity are increased in a rotating mode, and the drying support 200 can be folded when the drying is not performed, so that the occupied volume is reduced.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be able to cover the technical solutions disclosed in the present invention and the equivalent alternatives or modifications thereof within the scope of the present invention.

Claims (10)

1. The utility model provides a weaving machinery is with drying device who has cooling mechanism, a serial communication port, including drying chamber (100), stoving support (200), stoving roof (300), stoving bottom plate (400), cooling system (500) and controller (600), the inside of drying chamber (100) is provided with stoving support (200), and the top fixedly connected with stoving roof (300) of drying chamber (100), bottom fixedly connected with stoving bottom plate (400), and stoving roof (300) and stoving bottom plate (400) all are circularly, and curb plate (110) are the annular plate body, forms columniform stoving chamber between the three, be provided with cooling system (500) on stoving roof (300), cooling system (500) are connected with controller (600) through radio signal.

2. The drying device with the cooling mechanism for the textile machinery as claimed in claim 1, wherein the drying chamber (100) comprises side plates (110), side doors (120), air outlets (130) and support columns (140), the support columns (140) are arranged at four peripheral corners of the drying chamber (100), adjacent support columns (140) are connected with each other through the side plates (110), the side doors (120) are arranged on the side plates (110) at the front end of the drying chamber (100), the air outlets (130) are arranged at the corners of the lower end of each side plate (110), the side plates (110), the drying top plate (300) and the drying bottom plate (400) are rectangular, and a rectangular drying cavity is formed among the side plates, the side doors (120), the air outlets (130) and the drying bottom plate (400).

3. The drying device with the cooling mechanism for the textile machinery as claimed in claim 1, wherein the drying rack (200) comprises a main rotating motor (210), a rotating bottom plate (220), a rotating main shaft (230) and hanging mechanisms (240), the main rotating motor (210) is mounted on the drying bottom plate (400), a motor shaft of the main rotating motor (210) is connected with the rotating bottom plate (220) through a coupling, the upper end of the rotating bottom plate (220) is fixedly connected with the rotating main shaft (230), four hanging mechanisms (240) are arranged around the rotating main shaft (230), and the four hanging mechanisms (240) are annularly distributed.

4. The drying device with the temperature reducing mechanism for the textile machinery as claimed in claim 3, wherein the hanging mechanism (240) comprises a mounting back plate (241), an engaging panel (242), a cross bar assembly (243), side lugs (244), a rotating auxiliary shaft (245) and an adjusting bolt (246), a plurality of cross bar assemblies (243) which are arranged at equal intervals are fixedly connected between the mounting back plate (241) and the engaging panel (242) through bolts, the upper end and the lower end of the mounting back plate (241) are both fixedly connected with the side lugs (244), and the rotating auxiliary shaft (245) is screwed between the two side lugs (244) through the adjusting bolt (246).

5. The drying device with the temperature reducing mechanism for the textile machinery as claimed in claim 3, characterized in that the rotating main shaft (230) comprises a cylinder (231), a nozzle (232) and a pipeline interface (233), the cylinder (231) is provided with a cavity, the cavity is communicated with the nozzle (232) on the side wall of the cylinder (231), the upper end face of the cylinder (231) is provided with the pipeline interface (233), and the pipeline interface (233) is communicated with the cavity inside the cylinder (231).

6. The drying device with the temperature reducing mechanism for the textile machinery as claimed in claim 4, wherein the cross bar assembly (243) comprises a cross bar body (2431), a cross bar connecting shaft (2432), a transmission gear (2433), a cross bar base (2434), a transmission chain (2435) and a driving motor (2436), the side walls of the mounting back plate (241) and the connecting panel (242) are fixedly connected with the cross bar base (2434) through bolts, the two ends of the cross bar body (2431) are respectively provided with the cross bar connecting shaft (2432), the cross bar base (2434) on the mounting back plate (241) and the cross bar base (2434) on the connecting panel (242) are respectively and rotatably connected through the cross bar connecting shaft (2432), the transmission gear (2433) is fixedly connected on the cross bar connecting shaft (2432), and the transmission gears (2433) on the plurality of cross bar assemblies (243) are mutually connected through the transmission chain (2435), the cross bar connecting shaft (2432) of one cross bar assembly (243) is connected with a driving motor (2436).

7. The drying device with the cooling mechanism for the textile machinery as claimed in claim 4, characterized in that the upper end face and the lower end face of the rotary auxiliary shaft (245) are both provided with adjusting screw holes (247), the rotary auxiliary shaft (245) is screwed with adjusting bolts (246) through the adjusting screw holes (247), and the adjusting bolts (246) are welded on the side lugs (244).

8. The drying device with the cooling mechanism for the textile machinery as claimed in claim 1, wherein the cooling system (500) comprises an air inlet (510), a heater (520), a refrigerator (530), an air pump (540), a humidity sensor (550) and a temperature sensor (560), the cavity inside the drying chamber (100) is communicated with the air pump (540) through a pipeline, the air pump (540) is connected with the refrigerator (530) through a pipeline, the refrigerator (530) is connected with the heater (520) through a pipeline, the air inlet (510) is formed in the upper end of the heater (520), the pipelines on which the humidity sensor (550) and the temperature sensor (560) are mounted and connected with the air pump (540) are connected with valves in series, and a filter screen is arranged at the air inlet (510).

9. The drying device with a cooling mechanism for textile machinery as claimed in claim 8, characterized in that the humidity sensor (550) and the temperature sensor (560) are connected with the controller (600) through wireless signals, and the controller (600) is connected with the heater (520), the refrigerator (530), the air pump (540), the driving motor (2436) and the main rotating motor (210) through wireless signals.

10. A method of operating a drying device with a cooling mechanism for textile machines as claimed in any one of claims 1 to 9, characterized in that it comprises the following steps:

s101: high-temperature drying, namely inputting an instruction to the controller (600) to start the heater (520) and the air pump (540), driving external air to enter the drying cavity after drying by the air pump (540), and filling the dried high-temperature air into the drying cavity;

s102: drying at low temperature, starting a refrigerator (530), introducing gas which is dried and then cooled to a certain temperature into the drying cavity, and hanging the cloth to be dried;

s103: rotating and drying, wherein the main rotating motor (210) drives the rotating main shaft (230) to rotate, and drying is accelerated;

s104: controlling the temperature, and adjusting the refrigerating intensity of a refrigerator (530) after a temperature sensor (560) detects that the temperature in the drying cavity is different from a set temperature value, so as to control the temperature of gas entering the drying cavity;

s105: and controlling the humidity, and adjusting the heating intensity of a heater (520) after a humidity sensor (550) detects that the difference exists between the humidity in the drying cavity and a set humidity value, so as to control the humidity of the gas entering the drying cavity.

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