CN116480498B - Air inlet treatment equipment of generator - Google Patents

Abstract

The invention relates to the technical field of generators, in particular to air inlet treatment equipment of a generator, a mounting plate is fixedly connected into an air inlet box, an air flow channel is formed between the air inlet box and the mounting plate, a circulating treatment mechanism is connected onto the air inlet box and communicated with the air flow channel, a plurality of water-absorbing silica gel particles are arranged in the circulating treatment mechanism, and a driving mechanism for driving the circulating treatment mechanism to circularly convey the water-absorbing silica gel particles is connected onto the air inlet box. According to the invention, gaps in the storage rack are filled again after the water-absorbing silica gel particles are treated by hot gas in the storage box, and the water-absorbing silica gel particles in the mesh enclosure pipe are continuously replaced in the process of dehumidifying the gas in the gas flow channel, so that the water-absorbing silica gel particles in the mesh enclosure pipe continuously dehumidify the gas, the water-absorbing silica gel particles in the mesh enclosure pipe always keep high water absorption performance, and the dehumidifying filler does not need to be replaced, so that the dehumidifying effect on the gas is improved.

Description

Air inlet treatment equipment of generator

Technical Field

The invention relates to the technical field of generators, in particular to an air inlet treatment device of a generator.

Background

The diesel generator is installed and can consume the air in the computer lab when carrying out the electricity generation work at the computer lab, need adopt air inlet unit with gaseous leading-in computer lab in, for diesel generator work provides air, when leading-in gaseous humidity is great in the computer lab through air inlet unit with gaseous leading-in, lead to the inside moist of computer lab, thereby influence diesel generator's work, consequently, need carry out drying treatment to leading-in air, when setting up dry filler in the air inlet unit and drying gas, dry filler carries out the drying to gaseous after for a long time, dry filler's drying ability descends gradually, after dry filler's drying ability descends, the dehumidification effect to gas reduces, thereby lead to the gaseous humidity in the computer lab higher, and then influence diesel generator's work.

Disclosure of Invention

The invention aims to solve the defects that the drying capacity of a dry filler is gradually reduced and the dehumidifying effect on gas is reduced after the gas is dried for a long time in the prior art, so that the humidity of the gas entering a machine room is higher.

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

the utility model provides an air inlet treatment facility of generator, includes air inlet case, mounting panel, air current passageway, actuating mechanism and circulation processing mechanism, wherein:

the mounting plate is fixedly connected to the inside of the air inlet box, the air inlet box and the air flow channel are formed between the mounting plate, the circulating treatment mechanism is connected to the air inlet box and communicated with the air flow channel, a plurality of water-absorbing silica gel particles are arranged in the circulating treatment mechanism, and the air inlet box is connected with a driving mechanism for driving the circulating treatment mechanism to circularly convey the water-absorbing silica gel particles.

Preferably, the driving mechanism comprises a fixing plate, a motor, a first bevel gear and a driving assembly, wherein the fixing plate is fixedly connected to the air inlet box, the motor is fixedly connected to the fixing plate, the output end of the motor is fixedly connected with the first bevel gear through an output shaft, the driving assembly is rotatably connected to the mounting plate, the first bevel gear is meshed with the driving assembly, and the driving assembly is connected with the circulation processing mechanism, the first fan blade and the second fan blade.

Preferably, the driving assembly comprises a first rotating shaft, a second bevel gear, a first belt transmission part, a second belt transmission part and a third bevel gear, wherein the first rotating shaft is rotatably connected to the mounting plate, the second bevel gear is fixedly connected to the first rotating shaft, the second bevel gear is in meshed connection with the first bevel gear, the first rotating shaft is connected with the first fan blade through the first belt transmission part, the first rotating shaft is connected with the second fan blade through the second belt transmission part, the third bevel gear is fixedly connected to the first rotating shaft, and the third bevel gear is in meshed connection with the circulation processing mechanism.

Preferably, the circulation processing mechanism comprises a plurality of material storage frames, a material storage box, a collecting box, a material returning mechanism, a transmission component, third fan blades, a heating plate and a plurality of first through holes, wherein the material storage frames are fixedly connected to the material inlet box, the material storage frames penetrate through the mounting plate, the material storage frames are communicated with the air flow channel, the material storage frames are communicated with the collecting box, the collecting box is fixedly connected to the mounting plate, the upper ends of the material storage frames are communicated to the material storage box, the material returning mechanism is connected to the material inlet box, the bottom ends of the material returning mechanism penetrate through the mounting plate, the bottom ends of the material returning mechanism are connected with the third bevel gears, the collecting box is communicated with the material returning mechanism through a guide pipe, the transmission component is rotatably connected to the material storage box, the transmission component is connected with the material returning mechanism, the third fan blades are fixedly connected to the transmission component, the third fan blades are positioned above the material inlet box, and the material storage box is fixedly connected to the two sides of the material storing box, and the bottom ends of the material storing box are fixedly connected to the heating plate.

Preferably, the storage rack comprises a fixed pipe and a mesh enclosure pipe, the fixed pipe is fixedly connected with the air inlet box, one end of the fixed pipe is communicated with the bottom end of the storage box, the other end of the fixed pipe is communicated with the mesh enclosure pipe, the mesh enclosure pipe is communicated with the air flow channel, the bottom end of the mesh enclosure pipe penetrates through the mounting plate, and the bottom end of the mesh enclosure pipe is communicated with the collecting box.

Preferably, the feed back mechanism comprises a feeding shell, a second rotating shaft, a fourth bevel gear, a threaded feeding part and a discharging pipe, wherein the feeding shell is connected to the feeding box, the bottom end of the feeding shell penetrates through the mounting plate, the second rotating shaft is rotatably connected to the feeding shell, one end of the second rotating shaft is fixedly connected to the fourth bevel gear, the fourth bevel gear is in meshed connection with the third bevel gear, the other end of the second rotating shaft is fixedly connected to the threaded feeding part, the threaded feeding part is matched with the feeding shell, the threaded feeding part is connected with the transmission assembly, one end of the discharging pipe is communicated to the feeding shell, and the other end of the discharging pipe is communicated to the storage box.

Preferably, the fixed pipe is communicated with the air sweeping mechanism for cooling the water-absorbing silica gel particles, the air sweeping mechanism comprises a mounting groove, a heat conducting fin, a second through hole, a heat collecting frame, a first air duct and a second air duct, the mounting groove is formed in the fixed pipe, the heat conducting fin is arranged in the mounting groove, the second through hole is formed in the fixed pipe, the heat collecting frame is hermetically sleeved on the fixed pipe, the heat collecting frame is connected with the air inlet box, the second through hole is communicated with the heat collecting frame, one end of the first air duct is communicated with an air outlet, the other end of the first air duct is communicated with the heat collecting frame, one end of the second air duct is communicated with the heat collecting frame, and the other end of the second air duct is communicated with the storage box.

Preferably, the heat collection frame comprises a plurality of sealing covers, a cavity and connecting pipes, wherein the sealing covers are fixedly connected to the air inlet box, the sealing covers are in sealing connection with different fixed pipes, the sealing covers are sequentially communicated through the connecting pipes, the cavity is formed between the sealing covers and the fixed pipes, the second through holes are communicated with the cavity, and the cavity is communicated with the first air guide pipe and the second air guide pipe.

The air inlet treatment equipment of the generator has the beneficial effects that:

through filling the space in the storage frame again after the hot gas in the storage case handles the silica gel granule that absorbs water, in the gas to the air current passageway in-process of dehumidifying, the intraductal silica gel granule that absorbs water of screen panel is in continuous change for the intraductal silica gel granule that absorbs water of screen panel continuously dehumidifies gas, makes the intraductal silica gel granule that absorbs water of screen panel remain high water absorption ability all the time, need not to change dehumidification filler, thereby improves the dehumidification effect to gas.

Drawings

Fig. 1 is a schematic structural diagram of an air intake treatment device of a generator according to the present invention;

FIG. 2 is a schematic cross-sectional view of an air intake treatment apparatus of a generator according to the present invention;

fig. 3 is a schematic diagram of a connection structure between a circulation treatment mechanism and an air sweeping mechanism in an air intake treatment device of a generator according to the present invention;

fig. 4 is a schematic cross-sectional structure diagram of connection between a circulation treatment mechanism and an air sweeping mechanism in an air intake treatment device of a generator;

fig. 5 is a schematic view of a partial enlarged structure at a in fig. 4.

In the figure: the air intake box 1, the mounting plate 2, the air flow passage 3, the first fan blade 4, the second fan blade 5, the driving mechanism 6, the circulation processing mechanism 7, the air-sweeping mechanism 8, the fixing plate 61, the motor 62, the first bevel gear 63, the driving assembly 64, the first rotation shaft 641, the second bevel gear 642, the first belt transmission 643, the second belt transmission 644, the third bevel gear 645, the storage rack 71, the storage box 72, the collection box 73, the feeding mechanism 74, the transmission assembly 75, the third fan blade 76, the heating plate 77, the first through hole 78, the fixing pipe 711, the screen pipe 712, the feeding shell 741, the second rotation shaft 742, the fourth bevel gear 743, the screw feeding member 744, the discharging pipe 745, the third rotation shaft 751, the first gear 752, the fourth rotation shaft 753, the second gear 754, the mounting groove 81, the heat conductive sheet connecting pipe 82, the second through hole 83, the heat collecting rack 84, the first air duct 85, the second air duct 86, the sealing cover 841, the chamber 842, 843.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Example 1

Referring to fig. 1 to 4, an intake air treatment apparatus of a generator includes an intake box 1, a mounting plate 2, an air flow passage 3, a driving mechanism 6, and a circulation treatment mechanism 7, wherein:

the mounting plate 2 is fixedly connected into the air inlet box 1, an air flow channel 3 is formed between the air inlet box 1 and the mounting plate 2, the air flow channel 3 is convenient for air to flow in the air inlet box 1, the circulating treatment mechanism 7 is connected onto the air inlet box 1, the circulating treatment mechanism 7 enables water-absorbing silica gel particles to circulate and contact with the air in the air flow channel 3, the dehumidifying effect of the air is improved, the circulating treatment mechanism 7 is communicated with the air flow channel 3, a plurality of water-absorbing silica gel particles are arranged in the circulating treatment mechanism 7, the water-absorbing silica gel particles are used for dehumidifying the air flowing in the air flow channel 3, the air inlet box 1 is connected with a driving mechanism 6 for driving the circulating treatment mechanism 7 to circularly convey the water-absorbing silica gel particles, the mounting plate 2 is connected with a first fan blade 4 and a second fan blade 5 for accelerating the air flow, the driving mechanism 6 is connected with the first fan blade 4 and the second fan blade 5, an air inlet is formed in one end of the air inlet box 1, an air outlet is formed in the other end of the air inlet box 1, a controller is fixedly connected with the air inlet box 1, and the controller is in signal connection with the driving mechanism 6 and the circulating treatment mechanism 7;

referring to fig. 2, the driving mechanism 6 includes a fixing plate 61, a motor 62, a first bevel gear 63 and a driving assembly 64, the fixing plate 61 is fixedly connected to the air inlet box 1, the fixing plate 61 is used for installing the motor, the motor 62 is fixedly connected to the fixing plate 61, the motor 62 is connected with the controller through a wire, the output end of the motor 62 is fixedly connected with the first bevel gear 63 through an output shaft, the first bevel gear 63 is used for driving the driving assembly 64 to rotate, the driving assembly 64 is rotatably connected to the mounting plate 2, the first bevel gear 63 is in meshed connection with the driving assembly 64, the driving assembly 64 is connected with the circulation processing mechanism 7, the first fan blade 4 and the second fan blade 5, the controller controls the motor 62 to be electrified and started, the first bevel gear 63 drives the driving assembly 64 to rotate through the output shaft after the electrified starting, and the driving assembly 64 is driven to circularly convey the water-absorbing silica gel particles;

referring to fig. 2, the driving assembly 64 includes a first rotating shaft 641, a second bevel gear 642, a first belt transmission 643, a second belt transmission 644, and a third bevel gear 645, the first rotating shaft 641 is rotatably coupled to the mounting plate 2, the second bevel gear 642 is fixedly coupled to the first rotating shaft 641, the second bevel gear 642 is for driving the first rotating shaft 641 to rotate, the second bevel gear 642 is engaged with the first bevel gear 63, the first rotating shaft 641 is coupled to the first fan blade 4 through the first belt transmission 643, the first rotating shaft 641 is coupled to the second fan blade 5 through the second belt transmission 644, the third bevel gear 645 is fixedly coupled to the first rotating shaft 641, the third bevel gear 645 is engaged with the circulation processing mechanism 7, the first bevel gear 63 drives the second bevel gear 642 to rotate, the second bevel gear 642 drives the first rotating shaft 641 to rotate, the first rotating shaft 641 rotates at a certain rotating speed through the tooth number fit between the first bevel gear 63 and the second bevel gear 642, the first rotating shaft 641 drives the first fan blade 4 to rotate through the first belt transmission piece 643, the first rotating shaft 641 drives the second fan blade 5 to rotate through the second belt transmission piece 644, suction is generated on an air inlet after the first fan blade 4 rotates, external air enters the air flow channel 3 under the action of the suction, the second fan blade 5 absorbs air in the air flow channel 3 after rotating, and dehumidified air in the air flow channel 3 is discharged from an air outlet;

referring to fig. 3, the circulation processing mechanism 7 includes a plurality of storage shelves 71, a storage bin 72, a collection bin 73, a feed back mechanism 74, a transmission assembly 75, a third fan blade 76, a heating plate 77, and a plurality of first through holes 78, the plurality of storage shelves 71 are fixedly connected to the air inlet bin 1, the storage shelves 71 are used for dehumidifying the air in the air flow channel 3 by the water-absorbent silica gel particles, the bottom ends of the plurality of storage shelves 71 pass through the mounting plate 2, the storage shelves 71 are used for containing the water-absorbent silica gel particles, the plurality of storage shelves 71 are communicated with the air flow channel 3, the bottom ends of the plurality of storage shelves 71 are communicated with the collection bin 73, the collection bin 73 is fixedly connected to the mounting plate 2, the upper ends of the plurality of storage shelves 71 are communicated with the storage bin 72, the feed back mechanism 74 is connected to the air inlet bin 1, the feed back mechanism 74 is used for re-feeding the water-absorbent silica gel particles in the collection bin 73 into the storage bin 72, the bottom end of the feed back mechanism 74 passes through the mounting plate 2, the bottom end of the feed back mechanism 74 is connected with a third bevel gear 645, the collecting box 73 is communicated with the feed back mechanism 74 through a conduit, the feed back mechanism 74 is communicated with the storage box 72, the transmission component 75 is rotatably connected to the storage box 72, the transmission component 75 is used for driving the third fan blade 76 to rotate, the transmission component 75 is connected with the feed back mechanism 74, the third fan blade 76 is fixedly connected to the transmission component 75, the third fan blade 76 blows hot gas in the storage box 72 after rotating, the flowing hot gas contacts with water-absorbing silica gel particles in the storage box 72 to dry the water-absorbing silica gel particles, the wet gas generated by drying is released from the first through hole 78, the water-absorbing silica gel particles in the storage box 72 protect the water-absorbing performance, the third fan blade 76 is positioned above the inside of the storage box 72, the upper end of the storage box 72 is communicated with a dustproof air inlet, the heating plate 77 is fixedly connected into the storage box 72, the heating plate 77 is connected with a controller through a wire, the heating plate 77 is electrified and started to heat the air in the storage box 72, a plurality of first through holes 78 are formed at two sides of the bottom end of the storage box 72, the first through holes 78 are used for discharging wet air in the storage box 72, water-absorbent silica gel particles in the storage box 72 are filled into the storage rack 71 and the collecting box 73, the air flows in the air flow channel 3, the air flow is contacted with the water-absorbent silica gel particles through the storage rack 71, the water-absorbent silica gel particles are dehumidified and dried after being contacted with the air flow, the third bevel gear 645 rotates and drives the feed back mechanism 74 to start, the water-absorbent silica gel particles in the collecting box 73 gradually fall into the feed back mechanism 74 after the feed back mechanism 74 is started, the controller controls the electrifying and starting of the heating plate 77 to heat the air in the storage box 72, the feed back mechanism 74 drives the third fan blade 76 to rotate through the transmission component 75, the third fan blade 76 blows hot gas to the water-absorbing silica gel particles in the storage box 72 after rotating, the hot gas is contacted with the water-absorbing silica gel particles to dry and dehumidify the water-absorbing silica gel particles, so that the water-absorbing silica gel particles keep higher water absorption performance, moist gas generated by drying the water-absorbing silica gel particles is released from the first through holes 78, meanwhile, the hot gas contacted with the water-absorbing silica gel particles presses the water-absorbing silica gel particles downwards, so that the water-absorbing silica gel particles fall into the storage rack 71, after the water-absorbing silica gel particles in the storage box 73 are gradually reduced, gaps appear in the storage box 73, so that the bottom end of the storage rack 71 lacks support, the water-absorbing silica gel particles for dehumidifying the gas in the storage rack 71 fall downwards under the self gravity, the water-absorbing silica gel particles in the storage frame 71 are continuously replaced in the process of dehumidifying the gas in the gas flow channel 3, so that the water-absorbing silica gel particles in the storage frame 71 are continuously dehumidified, the gas in the gas flow channel 3 is gradually dehumidified, the water-absorbing silica gel particles in the storage frame 71 are gradually fallen into the storage box 73, the water-absorbing silica gel particles after water absorption in the storage box 73 are gradually fed into the storage box 72, the water-absorbing silica gel particles are re-filled in the storage frame 71 after the hot gas in the storage box 72 is processed, and the water-absorbing silica gel particles in the storage frame 71 are continuously replaced in the process of dehumidifying the gas in the gas flow channel 3, so that the water-absorbing silica gel particles in the storage frame 71 are not required to be dehumidified, and the water-absorbing silica gel particles in the storage frame 71 are not required to be continuously replaced, and the water-absorbing silica gel performance of the storage frame is not required to be constantly high, and the water-absorbing silica gel particles in the storage frame is required to be dehumidified;

referring to fig. 4, the storage rack 71 includes a fixing tube 711 and a mesh enclosure tube 712, the fixing tube 711 is fixedly connected to the air inlet box 1, the fixing tube 711 is used for fixing the mesh enclosure tube 712, one end of the fixing tube 711 is communicated to the bottom end of the storage box 72, the other end of the fixing tube 711 is communicated to the mesh enclosure tube 712, the mesh enclosure tube 712 is used for limiting the water-absorbent silica gel particles, meanwhile, the air is convenient to pass through the mesh enclosure tube 712 to contact with the water-absorbent silica gel particles, the mesh enclosure tube 712 is communicated with the air flow channel 3, the bottom end of the mesh enclosure tube 712 passes through the mounting plate 2, and the bottom end of the mesh enclosure tube 712 is communicated with the collecting box 73;

referring to fig. 4, the feed back mechanism 74 includes a feed housing 741, a second rotating shaft 742, a fourth bevel gear 743, a screw feed member 744 and a discharge pipe 745, the feed housing 741 is connected to the air inlet box 1, the bottom end of the feed housing 741 passes through the mounting plate 2, the second rotating shaft 742 is rotatably connected to the feed housing 741, the second rotating shaft 742 is used for driving the screw feed member 744 to rotate, one end of the second rotating shaft 742 is fixedly connected to the fourth bevel gear 743, the fourth bevel gear 743 is used for driving the second rotating shaft 742 to rotate, the fourth bevel gear 743 is engaged with the third bevel gear 645, the other end of the second rotating shaft 742 is fixedly connected to the screw feed member 744, the screw feed member 744 rotates to convey the water absorbing silica gel particles entering the feed housing 741 so that the water absorbing silica gel particles enter the discharge pipe 745, the screw feed member 744 is matched with the feed housing 741, the screw thread feeding part 744 is connected with the transmission component 75, one end of the discharging pipe 745 is communicated with the feeding shell 741, the other end of the discharging pipe 745 is communicated with the storage box 72, the third bevel gear 645 drives the fourth bevel gear 743 to rotate, the fourth bevel gear 743 drives the second rotating shaft 742 to rotate, the second rotating shaft 742 drives the screw thread feeding part 744 to rotate, under the tooth number matching of the third bevel gear 645 and the fourth bevel gear 743, the screw thread feeding part 744 rotates at a certain rotating speed, the water-absorbent silica gel particles in the collecting box 73 sequentially fall into the feeding shell 741, the screw thread feeding part 744 conveys the water-absorbent silica gel particles falling into the feeding shell 741 after rotating, so that the water-absorbent silica gel particles move upwards into the discharging pipe 745, and the water-absorbent silica gel particles are sent into the storage box 72 to be dried circularly;

referring to fig. 3, the transmission assembly 75 includes a third rotating shaft 751, a first gear 752, a fourth rotating shaft 753, and a second gear 754, one end of the third rotating shaft 751 is fixedly connected to the screw feeding member 744, the other end of the third rotating shaft 751 extends out of the feeding housing 741, the first gear 752 is fixedly connected to the third rotating shaft 751, the fourth rotating shaft 753 is rotatably connected to the storage box 72, the bottom end of the fourth rotating shaft 753 extends into the storage box 72, the bottom end of the fourth rotating shaft 753 is fixedly connected to the third fan blade 76, the second gear 754 is fixedly connected to the fourth rotating shaft 753, the second gear 754 is engaged with the first gear 752, the screw feeding member 744 drives the third rotating shaft 751 to rotate, the third rotating shaft 751 drives the first gear 752 to rotate, the first gear 752 drives the second gear 754 to rotate, the second gear 754 drives the fourth rotating shaft 753 to rotate, the fourth rotating shaft 753 drives the third fan blade 76 to rotate through the tooth number cooperation between the first gear 752 and the second gear 754, and the rotating speed of the third fan blade 76 is greater than the screw feeding member 744.

The working process comprises the following steps: when the generator needs to be electrified and started, the controller controls the motor 62 to drive the first bevel gear 63 to rotate through the output shaft after the motor 62 is electrified and started, the first bevel gear 63 drives the second bevel gear 642 to rotate, the second bevel gear 642 drives the first rotating shaft 641 to rotate, the first rotating shaft 641 rotates at a certain rotating speed through the tooth number fit between the first bevel gear 63 and the second bevel gear 642, the first rotating shaft 641 drives the first fan blade 4 to rotate through the first belt transmission piece 643, the first rotating shaft 641 drives the second fan blade 5 to rotate through the second belt transmission piece 644, suction is generated on the air inlet after the first fan blade 4 rotates, external air enters the air flow channel 3 under the action of the suction, water-absorbing silica gel particles in the storage box 72 fill the mesh cover pipe 712 and the collecting box 73, the air flows in the air flow channel 3 through the contact of the water-absorbing silica gel particles, the air flow is dehumidified and dried after the water-absorbing silica gel particles are contacted with the air flow, the air flow in the air flow channel 3 is sucked, and the air in the air flow channel 3 after the second fan blade 5 rotates, and the air in the air flow channel 3 is discharged from the air outlet through the mesh cover;

the first rotating shaft 641 further drives the third bevel gear 645 to rotate, the third bevel gear 645 drives the fourth bevel gear 743 to rotate, the fourth bevel gear 743 drives the second rotating shaft 742 to rotate, the second rotating shaft 742 drives the threaded feeding member 744 to rotate, under the cooperation of the teeth of the third bevel gear 645 and the fourth bevel gear 743, the threaded feeding member 744 rotates at a certain rotating speed, the water-absorbent silica gel particles in the collecting tank 73 sequentially fall into the feeding shell 741, the threaded feeding member 744 rotates and then conveys the water-absorbent silica gel particles falling into the feeding shell 741, so that the water-absorbent silica gel particles move upwards into the discharging tube 745, the water-absorbent silica gel particles are conveyed into the storage tank 72, the water-absorbent silica gel particles are circularly dried and used, meanwhile, the controller controls the heating plate 77 to be electrified and started, the gas in the storage tank 72 is heated after the heating plate 77 is electrified and the threaded feeding member 744 drives the third rotating shaft 751 to rotate, the third rotating shaft 751 drives the first gear 752 to rotate, the first gear 752 drives the second gear 754 to rotate, the second gear 754 drives the fourth rotating shaft 753 to rotate, the fourth rotating shaft 753 drives the third fan blade 76 to rotate, through the tooth number fit between the first gear 752 and the second gear 754, the rotating speed of the third fan blade 76 is higher than that of the screw feeding piece 744, the third fan blade 76 rotates rapidly, heated gas is blown onto the water-absorbing silica gel particles in the storage box 72 after the third fan blade 76 rotates, the heated gas is dried and dehumidified after being contacted with the water-absorbing silica gel particles, so that the water-absorbing silica gel particles keep higher water absorption performance, moist gas generated by drying of the water-absorbing silica gel particles is released from the first through hole 78, and meanwhile, the hot gas contacted with the water-absorbing silica gel particles extrudes the water-absorbing silica gel particles downwards, so that the water-absorbing silica gel particles fall into the storage box 71;

after the water-absorbing silica gel particles in the collecting box 73 are gradually reduced, gaps appear in the collecting box 73, so that the bottom end of the mesh enclosure pipe 712 lacks support, the water-absorbing silica gel particles for dehumidifying the gas in the mesh enclosure pipe 712 drop downwards under the self gravity under the lack of support, the water-absorbing silica gel particles sequentially drop into the collecting box 73 from the bottom of the mesh enclosure pipe 712, after the water-absorbing silica gel particles at the bottom of the mesh enclosure pipe 712 drop, gaps appear on the upper part of the fixing pipe 711, the dried water-absorbing silica gel particles in the storage box 72 refill the gaps in the storage rack 71, the water-absorbing silica gel particles in the storage rack 71 always maintain high water-absorbing performance, the water-absorbing silica gel particles in the refilled storage rack 71 contact with the gas in the gas flow channel 3, the air is dehumidified, the water-absorbing silica gel particles in the mesh enclosure pipe 712 gradually fall into the collecting box 73 after the air in the air flow channel 3 is dehumidified, the water-absorbing silica gel particles after water absorption in the collecting box 73 are gradually fed into the storage box 72 by the feed back mechanism 74, gaps in the storage rack 71 are filled again after the hot air in the storage box 72 is used for treating the water-absorbing silica gel particles, the water-absorbing silica gel particles in the mesh enclosure pipe 712 are continuously replaced in the process of dehumidifying the air in the air flow channel 3, the water-absorbing silica gel particles in the mesh enclosure pipe 712 continuously dehumidify the air, and the water-absorbing silica gel particles in the mesh enclosure pipe 712 always keep high water absorption performance without replacing a dehumidifying filler, so that the dehumidifying effect on the air is improved.

Example 2

The heated air is blown onto the water-absorbing silica gel particles in the storage box 72 after the third fan blade 76 rotates, the heated air is dried and dehumidified after contacting with the water-absorbing silica gel particles, the temperature of the water-absorbing silica gel particles is raised after the water-absorbing silica gel particles are heated and dried, the warmed water-absorbing silica gel particles fall into the mesh enclosure tube 712, when the air in the air flow channel 3 dehumidifies, the air is contacted with the warmed water-absorbing silica gel particles, the water-absorbing silica gel particles warm the air in the air flow channel 3, thereby raising the temperature of the air released from the air outlet, after the warmed air is introduced into the machine room, the temperature in the machine room is raised, the diesel generator releases heat after the diesel generator operates, the diesel generator is in a high temperature environment, thereby affecting the operation of the diesel generator, and referring to fig. 4 to 5, as another preferred embodiment of the invention, on the basis of example 1, the fixed pipe 711 is communicated with the air sweeping mechanism 8 for cooling the water-absorbing silica gel particles, the air sweeping mechanism 8 comprises a mounting groove 81, a heat conducting fin 82, a second through hole 83, a heat collecting frame 84, a first air conducting pipe 85 and a second air conducting pipe 86, the mounting groove 81 is arranged in the fixed pipe 711, the heat conducting fin 82 is arranged in the mounting groove 81, the second through hole 83 is arranged on the fixed pipe 711, the heat collecting frame 84 is hermetically sleeved on the fixed pipe 711, the heat collecting frame 84 is connected with the air inlet box 1, the second through hole 83 is communicated with the heat collecting frame 84, one end of the first air conducting pipe 85 is communicated with an air outlet, the other end of the first air conducting pipe 85 is communicated with the heat collecting frame 84, one end of the second air conducting pipe 86 is communicated with the heat collecting frame 84, the other end of the second air conducting pipe 86 is communicated with the storage box 72, when the heated water-absorbing silica gel particles fall into the fixed pipe 711, the heated water-absorbing silica gel particles are contacted with the heat conducting fin 82, the heat conducting fin 82 conducts heat from the warmed water-absorbing silica gel particles, the heat on the heat conducting fin 82 is released into the heat collecting frame 84 through the second through holes 83, the heat conducted by the heat conducting fin 82 is collected in the heat collecting frame 84, a part of dry gas released from the air outlet enters the first air duct 85, the dry gas is conducted into the heat collecting frame 84 through the first air duct 85, the dry gas conducted into the heat collecting frame 84 drives the heat in the heat collecting frame 84 to flow out from the second air duct 86, the discharged heat gas is conducted into the storage box 72 for recycling the heat, meanwhile, the humidity in the storage box 72 is reduced after the dry gas is conducted into the storage box 72, after the heat in the heat collecting frame 84 flows out from the second air duct 86, the temperature in the heat accumulation frame 84 is reduced, the temperature on the heat conducting fin 82 is higher than the temperature in the heat accumulation frame 84, so that the heat on the heat conducting fin 82 conveniently enters the heat accumulation frame 84, the temperature of the heat conducting fin 82 is reduced after the heat on the heat conducting fin 82 enters the heat accumulation frame 84, after the heat conducting fin 82 contacts with the heated water-absorbing silica gel particles, the heat on the water-absorbing silica gel particles is transferred to the heat conducting fin 82 under heat conduction, and therefore the temperature of the water-absorbing silica gel particles is reduced, after the cooled water-absorbing silica gel particles fall into the storage box 72, the gas in the gas flow channel 3 is dehumidified, and the temperature of the gas is not increased after the reduced water-absorbing silica gel particles contact with the gas during dehumidification;

the heat collecting frame 84 comprises a plurality of sealing covers 841, a cavity 842 and a connecting pipe 843, the sealing covers 841 are fixedly connected to the air inlet box 1, the sealing covers 841 are in sealing connection with different fixing pipes 711, the sealing covers 841 are sequentially communicated through the connecting pipe 843, the cavity 842 is formed between the sealing covers 841 and the fixing pipes 711, the cavity 842 is used for collecting heat released from the second through holes 83, the second through holes 83 are communicated with the cavity 842, and the cavity 842 is communicated with the first air guide pipe 85 and the second air guide pipe 86.

The working process comprises the following steps: when the heated water-absorbing silica gel particles fall into the fixed pipe 711, the heated water-absorbing silica gel particles are in contact with the heat conducting fin 82, the heat conducting fin 82 guides out the heat on the heated water-absorbing silica gel particles, the heat on the heat conducting fin 82 is released into the cavity 842 through the second through holes 83, the heat guided out by the heat conducting fin 82 is concentrated in the cavity 842, a part of dry gas released from the air outlet enters the first air guide pipe 85, the dry gas is guided into the cavity 842 through the first air guide pipe 85, the dry gas introduced into the cavity 842 drives the heat in the cavity 842 to flow out from the second air guide pipe 86, the discharged heat gas is guided into the storage box 72, the humidity in the storage box 72 is reduced after the dry gas is guided into the storage box 72, the temperature in the cavity 842 is reduced after the heat in the cavity 842 flows out from the second air guide pipe 86, the temperature in the cavity 842 is higher than the temperature in the cavity 842, the temperature in the heat conducting fin 82 is convenient to enter the cavity 842, the temperature of the heat conducting fin 82 is reduced after the heat in the cavity 842, the temperature of the silica gel 82 is guided into the cavity 842, the heat conducting fin 82 flows out of the second air guide pipe 86 from the second air guide pipe 86 through the second air guide pipe, the heat is guided into the air guide pipe 86 through the second air guide pipe, the heat-guide pipe is discharged from the second air guide pipe 72, the heat is discharged into the air guide box 72, the air is cooled down, the temperature of the silica gel particles is not influenced by the heat-absorbing silica gel particles, and the temperature of the air is cooled down when the air is cooled down, and the air is cooled down in the temperature of the air is cooled down, and the air is cooled down in the air through the air, the air is cooled down when the temperature is cooled down by the air, the air is cooled down and cooled down in the air, the temperature air is cooled down and cooled down by the air.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims (3)

1. The utility model provides an air inlet treatment facility of generator, its characterized in that includes air inlet case (1), mounting panel (2), air current passageway (3), actuating mechanism (6) and circulation processing mechanism (7), wherein:

the air inlet box (1) is fixedly connected with the inside of the air inlet box (1), an air flow channel (3) is formed between the air inlet box (1) and the mounting plate (2), the circulating treatment mechanism (7) is connected to the air inlet box (1), the circulating treatment mechanism (7) is communicated with the air flow channel (3), a plurality of water-absorbing silica gel particles are arranged in the circulating treatment mechanism (7), and the air inlet box (1) is connected with a driving mechanism (6) for driving the circulating treatment mechanism (7) to circularly convey the water-absorbing silica gel particles;

the driving mechanism (6) comprises a fixed plate (61), a motor (62), a first bevel gear (63) and a driving assembly (64), wherein the fixed plate (61) is fixedly connected to the air inlet box (1), the motor (62) is fixedly connected to the fixed plate (61), the output end of the motor (62) is fixedly connected with the first bevel gear (63) through an output shaft, the driving assembly (64) is rotatably connected to the mounting plate (2), the first bevel gear (63) is in meshed connection with the driving assembly (64), and the driving assembly (64) is connected with the circulating processing mechanism (7), the first fan blade (4) and the second fan blade (5);

the driving assembly (64) comprises a first rotating shaft (641), a second bevel gear (642), a first belt transmission part (643), a second belt transmission part (644) and a third bevel gear (645), the first rotating shaft (641) is rotatably connected to the mounting plate (2), the second bevel gear (642) is fixedly connected to the first rotating shaft (641), the second bevel gear (642) is in meshed connection with the first bevel gear (63), the first rotating shaft (641) is connected with a first fan blade (4) through the first belt transmission part (643), the first rotating shaft (641) is connected with a second fan blade (5) through the second belt transmission part (644), the third bevel gear (645) is fixedly connected to the first rotating shaft (641), and the third bevel gear (645) is in meshed connection with the circulation processing mechanism (7);

the circulating treatment mechanism (7) comprises a plurality of material storage frames (71), a material storage box (72), a collection box (73), a material return mechanism (74), a transmission assembly (75), a third fan blade (76), a heating plate (77) and a plurality of first through holes (78), wherein the material storage frames (71) are fixedly connected to the air inlet box (1), the bottom ends of the material storage frames (71) penetrate through the mounting plate (2), the material storage frames (71) are communicated with the airflow channel (3), the bottom ends of the material storage frames (71) are communicated to the collection box (73), the collection box (73) is fixedly connected to the mounting plate (2), the material return mechanism (74) is connected to the air inlet box (1), the bottom ends of the material return mechanism (74) penetrate through the mounting plate (2), the bottom ends of the material return mechanism (74) are connected with the third bevel gear (645), the material storage frames (71) are communicated with the transmission assembly (72), the material storage assembly (72) can be connected to the material return mechanism (74), the third fan blades (76) are fixedly connected to the transmission assembly (75), the third fan blades (76) are located above the inside of the storage box (72), the heating plate (77) is fixedly connected to the inside of the storage box (72), and a plurality of first through holes (78) are formed in two sides of the bottom end of the storage box (72);

the storage rack (71) comprises a fixed pipe (711) and a mesh enclosure pipe (712), the fixed pipe (711) is fixedly connected with the air inlet box (1), one end of the fixed pipe (711) is communicated to the bottom end of the storage box (72), the other end of the fixed pipe (711) is communicated to the mesh enclosure pipe (712), the mesh enclosure pipe (712) is communicated with the airflow channel (3), the bottom end of the mesh enclosure pipe (712) penetrates through the mounting plate (2), and the bottom end of the mesh enclosure pipe (712) is communicated with the collection box (73);

the utility model discloses a heat collection device, including fixed pipe (711), fixed pipe (711) are gone up the intercommunication and are used for right the mechanism (8) is swept to the wind that absorbs water silica gel granule carries out the cooling, mechanism (8) are swept to the wind includes mounting groove (81), conducting strip (82), second through-hole (83), heat collection frame (84), first air duct (85) and second air duct (86), set up in fixed pipe (711) mounting groove (81), conducting strip (82) set up in mounting groove (81), second through-hole (83) set up extremely on fixed pipe (711), heat collection frame (84) sealed cup joint to on fixed pipe (711), heat collection frame (84) are connected air inlet case (1), second through-hole (83) intercommunication heat collection frame (84), the one end of first air duct (85) communicates to the air outlet, the other end of first air duct (85) communicates to on heat collection frame (84), the one end of second air duct (86) communicates to heat collection frame (84), the other end communicates on the heat collection frame (72).

2. The air intake treatment device of the generator according to claim 1, wherein the feed back mechanism (74) comprises a feeding shell (741), a second rotating shaft (742), a fourth bevel gear (743), a threaded feeding member (744) and a discharging pipe (745), the feeding shell (741) is connected to the air intake box (1), the bottom end of the feeding shell (741) passes through the mounting plate (2), the second rotating shaft (742) is rotatably connected to the feeding shell (741), one end of the second rotating shaft (742) is fixedly connected to the fourth bevel gear (743), the fourth bevel gear (743) is in meshed connection with the third bevel gear (645), the other end of the second rotating shaft (742) is fixedly connected to the threaded feeding member (744), the threaded feeding member (744) is matched with the feeding shell (741), the threaded feeding member (744) is connected to the transmission assembly (75), one end of the discharging pipe (745) is communicated to the feeding shell (741), and the other end of the discharging pipe (745) is communicated to the air storage box (72).

3. The air intake treatment device of the generator according to claim 2, wherein the heat collecting frame (84) comprises a plurality of sealing covers (841), a chamber (842) and a connecting pipe (843), the plurality of sealing covers (841) are fixedly connected to the air intake box (1), the plurality of sealing covers (841) are hermetically sleeved with different fixed pipes (711), the plurality of sealing covers (841) are sequentially communicated through the connecting pipe (843), the chamber (842) is formed between the sealing covers (841) and the fixed pipes (711), the second through hole (83) is communicated with the chamber (842), and the chamber (842) is communicated with the first air guide pipe (85) and the second air guide pipe (86).