CN112033126A - Energy-saving drying device capable of drying fabrics in different sizes - Google Patents

Abstract

The invention relates to the field of fabric processing, and discloses an energy-saving drying device capable of drying fabrics with different sizes, which comprises a main box body, wherein a drying cavity is arranged in the main box body, the upper side of the drying cavity is communicated with a ventilation cavity, the rear side of the drying cavity is provided with a friction block sliding cavity, the rear end wall of the friction block sliding cavity is rotationally and fittingly connected with a fabric rotating shaft which extends forwards and penetrates through the friction block sliding cavity and the drying cavity to the front end wall of the drying cavity, the fabric rotating shaft is fixedly connected with a fixed baffle plate positioned in the drying cavity, hot air is directly contacted with the fabrics by utilizing the hot air through cavity on the drying rotary block, so that the fabrics are dried more quickly and more efficiently, meanwhile, the rotating direction of the drying rotary block is opposite to the moving direction of the fabrics, the problem that the drying is not thorough due to the fact that the places without the hot air on the drying rotary block are contacted with the fabrics for a, the drying effect can be ensured by reducing hot air, and the effect of reducing energy consumption when drying small-size cloth is achieved.

Description

Energy-saving drying device capable of drying fabrics in different sizes

Technical Field

The invention relates to the field of fabric processing, in particular to an energy-saving drying device capable of drying fabrics with different sizes.

Background

The surface fabric is dried and is one of important process in the surface fabric processing aftertreatment, if dry not thoroughly to make the surface fabric go mildy in the later stage is stored very easily, go out the face spot, influence the later stage use of surface fabric, present surface fabric drying-machine, generally pull open the surface fabric, then let in steam and dry it, because steam has passed through the air and has contacted with the cloth again, make heat in the steam consumed, not only caused the energy waste, still lead to the stoving speed low, efficiency is not high, simultaneously can't be to the surface fabric of not unidimensional, and select different heats to dry, this also greatly increased the energy resource consumption.

Disclosure of Invention

The invention aims to provide an energy-saving drying device capable of drying fabrics with different sizes, which can overcome the defects in the prior art, thereby improving the practicability of equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to an energy-saving drying device capable of drying fabrics with different sizes, which comprises a main box body, wherein a drying cavity is arranged in the main box body, the upper side of the drying cavity is communicated with a ventilation cavity, the rear side of the drying cavity is provided with a friction block sliding cavity, the rear end wall of the friction block sliding cavity is connected with a fabric rotating shaft which extends forwards and penetrates through the friction block sliding cavity and the drying cavity to the front end wall of the drying cavity in a rotating fit manner, the fabric rotating shaft is fixedly connected with a fixed baffle plate positioned in the drying cavity, a baffle plate rotating seat is arranged in the drying cavity, a sliding baffle plate cavity with a forward opening is arranged in the baffle plate rotating seat, the rear side of the sliding baffle plate cavity is communicated with a rotating shaft through cavity with a backward opening, the fabric rotating shaft penetrates through the rotating shaft through cavity, and the sliding baffle plate cavity is connected with a sliding baffle plate which is, the sliding baffle is internally and cooperatively connected with a fixed knob which can be abutted against the outer circular surface of the sliding baffle in a matching way, the sliding cavity of the friction block is internally and slidably connected with friction sliding blocks which are bilaterally symmetrical by taking the fabric rotating shaft as the center, the side end surface of the friction sliding block close to the fabric rotating shaft is fixedly connected with a friction block which is abutted against the outer circular surface of the fabric rotating shaft, the side end surface of the friction sliding block far away from the fabric rotating shaft is fixedly connected with friction block springs which are bilaterally symmetrical by taking the fabric rotating shaft as the center, the rear end surface of the baffle rotating seat is fixedly connected with a pull rope, the rear side of the drying cavity is provided with a sliding gear cavity positioned at the right side of the sliding cavity of the friction block, the right side of the sliding gear cavity is communicated with a long gear cavity, and the lower, the front side of the sliding gear cavity is communicated with a connecting shaft cavity which extends forwards and penetrates through the gear transmission cavity to the opening forwards, a bevel gear transmission cavity which is located on the right side of the connecting shaft cavity is arranged between the gear transmission cavity and the long gear cavity, and the right side of the bevel gear transmission cavity is provided with a sliding bevel gear cavity.

On the basis of the technical scheme, a rotating seat connecting shaft which extends forwards into a drying cavity is connected in a connecting shaft cavity in a rotating fit manner, a drying rotating seat is fixedly connected to the front end face of the rotating seat connecting shaft, a fan shaft through cavity which extends backwards through the rotating seat connecting shaft to the opening upwards is arranged in the drying rotating seat, a rotating block rotating cavity with a forward opening is communicated with the front side of the fan shaft through cavity, a drying rotating block is fixedly connected in the rotating block rotating cavity, a drying rotating shaft which extends forwards into the front end wall of the drying cavity and is connected with the front end wall of the drying cavity in a rotating fit manner is fixedly connected to the front end face of the drying rotating block, a heating block sliding cavity with a backward opening is arranged in the drying rotating block, a plurality of hot air through cavities which are circumferentially distributed at equal intervals by taking the heating block sliding cavity as the center are arranged in a penetrating manner inside and outside the side wall of the heating block sliding cavity, and a heating block, the heating device is characterized in that a heating cavity with a forward opening is arranged in the heating block, a heating pipe is fixedly connected to the inner wall of the heating cavity, and the rear end wall of the heating cavity is connected with a fan shaft which extends forwards and backwards in the heating cavity and penetrates through the rotating block rotating cavity, the fan shaft penetrating cavity and the shaft connecting cavity to the sliding gear cavity.

On the basis of the technical scheme, the tail end of the rear side of the fan shaft is fixedly connected with a sliding gear, the front end face of the sliding gear is fixedly connected with a gear fixing block which is in rotating fit connection with the fan shaft, the gear fixing block is in rotating fit connection with a gear block rotating seat, a fan shaft through cavity is arranged in the gear block rotating seat in a front-back through mode, a sliding gear spring is fixedly connected between the front end face of the gear block rotating seat and the front end wall of the sliding gear cavity, the fan shaft penetrates through the fan shaft through cavity, the other end of the stay cord is fixedly connected with the front end face of the gear block rotating seat, a pinion gear positioned in the gear transmission cavity is fixedly connected on a rotating seat connecting shaft, a long gear shaft which extends backwards and penetrates through the bevel gear transmission cavity into the long gear cavity is rotatably connected on the rear end wall of the gear transmission cavity in a matching mode, and a large gear meshed, the bevel gear transmission mechanism is characterized in that a long gear is fixedly connected to a long gear shaft and located in a long gear cavity, a driven bevel gear is fixedly connected to the long gear shaft and located in a bevel gear transmission cavity, a sliding pinion cavity is arranged on the right side of the sliding bevel gear cavity, a sliding bevel gear shaft which extends through the sliding bevel gear cavity to the sliding pinion cavity is connected to the right end wall of the bevel gear transmission cavity in a rotating fit mode, and a driving bevel gear meshed with the driven bevel gear is fixedly connected to the left end of the sliding bevel gear shaft in a tail-end fixing mode.

On the basis of the technical scheme, a sliding shaft sleeve positioned in the sliding bevel gear cavity is connected to the sliding bevel gear shaft in a spline fit manner, a sliding shaft sleeve spring is fixedly connected between the left end face of the sliding shaft sleeve and the left end wall of the sliding bevel gear cavity, a sliding bevel gear is fixedly connected to the sliding shaft sleeve, the tail end of the lower side of the fan shaft is fixedly connected to a fan positioned in the heating cavity and positioned at the rear side of the heating pipe, a rear sliding cavity is communicated between the sliding bevel gear cavity and the drying cavity, a front sliding cavity is communicated with the front side of the drying cavity, a sliding block cavity is communicated with the front side of the front sliding cavity, a belt wheel transmission cavity is arranged on the right side of the drying cavity, a driven belt wheel shaft extending through the sliding block cavity to the belt wheel transmission cavity rightwards is connected to the left end wall of the sliding block cavity in a rotating fit manner, and a sliding block connected with the The inner rotating fit is connected with a recovery shaft which extends backwards and penetrates through the front sliding cavity, the drying cavity and the rear sliding cavity to the sliding bevel gear cavity, and the tail end of the rear side of the recovery shaft is fixedly connected with a recovery shaft bevel gear meshed with the sliding bevel gear.

On the basis of the technical scheme, a motor fixedly connected with the main box body is arranged at the rear side of the sliding bevel gear cavity, a transmission belt cavity is arranged at the right side of the motor, the right end face of the motor is fixedly connected with a motor shaft extending rightwards into the transmission belt cavity, the tail end of the right side of the motor shaft is fixedly connected with a motor belt wheel, a transmission shaft extending rightwards into the sliding bevel gear cavity and extending leftwards into the transmission belt cavity is connected in a rotating fit manner in the right end wall of the transmission belt cavity, a transmission shaft gear is fixedly connected at the left end of the transmission shaft, a transmission belt is connected between the transmission shaft gear and the motor belt wheel in a power fit manner, a magnetic sliding shaft sleeve positioned in the sliding bevel gear cavity is connected on the transmission shaft in a spline fit manner, and electromagnets which are bilaterally symmetrical by taking the magnetic sliding shaft sleeve as a center are fixedly connected in, the electromagnet and the magnetic sliding shaft sleeve are fixedly connected with a magnet shaft sleeve spring, the magnetic sliding shaft sleeve is fixedly connected with a sliding pinion, and the tail end of the right side of the sliding bevel gear shaft is fixedly connected with a left gear which can be meshed with the sliding pinion.

On the basis of the technical scheme, the right end wall of the sliding pinion cavity is connected with a driving pulley shaft which extends rightwards into the pulley transmission cavity and leftwards into the sliding pinion cavity in a rotating fit mode, the left end of the driving pulley shaft is fixedly connected with a right gear which can be meshed with the sliding pinion, the right end of the driving pulley shaft is fixedly connected with a driving pulley, the right end of the driven pulley shaft is fixedly connected with a driven pulley, a belt is connected between the driven pulley and the driving pulley in a power fit mode, and the recovery shaft is fixedly connected with a recovery sleeve positioned in the drying cavity.

The invention has the beneficial effects that: utilize the steam on the rotatory piece of stoving to lead to the chamber with steam and cloth direct contact, make cloth stoving quicker, efficiency is higher, the rotatory piece of stoving rotates the direction opposite with cloth direction of motion simultaneously, avoided the local long-time contact cloth that does not have steam on the rotatory piece of stoving and lead to drying not thorough problem, the device is owing to heating block sliding chamber space reduces when drying small-size cloth simultaneously, make and reduce steam and also can guarantee the stoving effect, thereby the effect of energy consumption is reduced when having reached the small-size cloth of stoving.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view of the overall structure of an energy-saving drying device for drying fabrics with different sizes according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is an enlarged schematic view of B of FIG. 2;

FIG. 4 is an enlarged schematic view of C in FIG. 2;

fig. 5 is an enlarged schematic view of D in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The energy-saving drying device capable of drying the fabrics with different sizes, which is described in conjunction with the attached drawings 1-5, comprises a main box body 10, a drying cavity 14 is arranged in the main box body 10, an air vent cavity 11 is communicated with the upper side of the drying cavity 14, a friction block sliding cavity 47 is arranged at the rear side of the drying cavity 14, a fabric rotating shaft 41 which extends forwards and penetrates through the friction block sliding cavity 47 and the drying cavity 14 to the front end wall of the drying cavity 14 is connected in a rotating and matching manner in the rear end wall of the friction block sliding cavity 47, a fixed baffle 42 which is positioned in the drying cavity 14 is fixedly connected to the fabric rotating shaft 41, a baffle rotating seat 17 is arranged in the drying cavity 14, a sliding baffle cavity 44 with a forward opening is arranged in the baffle rotating seat 17, a rotating shaft through cavity 45 with a backward opening is communicated with the rear side of the sliding baffle cavity 44, and the fabric rotating shaft 41 penetrates through the, the sliding baffle cavity 44 is connected with a sliding baffle 16 in a sliding fit connection with the fabric rotating shaft 41, the sliding baffle 16 is connected with a fixed knob 43 capable of abutting against the outer circular surface of the sliding baffle 16 in a threaded fit manner, the friction block sliding cavity 47 is connected with friction sliding blocks 18 in a sliding fit manner, the friction sliding blocks 18 are bilaterally symmetrical with the fabric rotating shaft 41 as the center, the friction block 19 abutting against the outer circular surface of the fabric rotating shaft 41 is fixedly connected with the end surface of the friction sliding block 18 close to the fabric rotating shaft 41, the friction block springs 46 are fixedly connected between the end surface of the friction sliding block 18 far away from the fabric rotating shaft 41 and the left and right end walls of the friction block sliding cavity 47, the left and right symmetrical with the fabric rotating shaft 41 as the center, the rear end surface of the baffle rotating seat 17 is fixedly connected with a pull rope 20, and the rear side of the drying cavity 14, sliding gear chamber 23 right side intercommunication is equipped with long gear chamber 71, sliding gear chamber 23 downside is located being equipped with gear drive chamber 57 of long gear chamber 71 front side, sliding gear chamber 23 front side intercommunication is equipped with and extends forward and runs through gear drive chamber 57 to the forward connecting shaft chamber 68 of opening, gear drive chamber 57 with be equipped with the bevel gear transmission chamber 50 that is located connecting shaft chamber 68 right side between the long gear chamber 71, the bevel gear transmission chamber 50 right side is equipped with sliding bevel gear chamber 48.

In addition, in one embodiment, the coupling shaft cavity 68 is connected with a rotating base coupling shaft 67 which extends forward into the drying cavity 14 in a rotationally-matched manner, the front end surface of the rotating base coupling shaft 67 is fixedly connected with the drying rotating base 12, the drying rotating base 12 is provided with a fan shaft through cavity 66 which extends backward through the rotating base coupling shaft 67 to have an upward opening, the front side of the fan shaft through cavity 66 is communicated with a rotating block rotating cavity 64 with a forward opening, the rotating block rotating cavity 64 is fixedly connected with a drying rotating block 39, the front end surface of the drying rotating block 39 is fixedly connected with a drying rotating shaft 38 which extends forward into the front end wall of the drying cavity 14 and is connected with the front end wall of the drying cavity 14 in a rotationally-matched manner, the drying rotating block 39 is provided with a heating block sliding cavity 40 with a backward opening, the side wall of the heating block sliding cavity 40 is internally and externally provided with a plurality of hot air through cavities 63 which are circumferentially distributed at equal intervals by taking the heating, heating block sliding cavity 40 sliding fit is connected with heating block 62 in, be equipped with the heating chamber 61 that the opening is forward in the heating block 62, fixedly connected with heating pipe 60 on the heating chamber 61 inner wall, heating chamber 61 rear end wall internal rotation fit is connected with and extends forward to the heating chamber 61 is interior to be extended backward and is run through rotating block rotating cavity 64 the fan axle runs through chamber 66 even axle chamber 68 extremely fan axle 22 in the sliding gear chamber 23.

In addition, in one embodiment, a sliding gear 70 is fixedly connected to the rear end of the fan shaft 22, a gear fixing block 69 which is connected with the fan shaft 22 in a rotating fit manner is fixedly connected to the front end face of the sliding gear 70, a gear block rotating seat 21 is connected with the gear fixing block 69 in a rotating fit manner, a fan shaft through cavity 13 is arranged in the gear block rotating seat 21 in a front-back through manner, a sliding gear spring 24 is fixedly connected between the front end face of the gear block rotating seat 21 and the front end wall of the sliding gear cavity 23, the fan shaft 22 penetrates through the fan shaft through cavity 13, the other end of the pull rope 20 is fixedly connected with the front end face of the gear block rotating seat 21, a pinion 65 which is positioned in the gear transmission cavity 57 is fixedly connected to the rotating seat connecting shaft 67, a long gear shaft 25 which extends through the bevel gear transmission cavity 50 to the long gear cavity 71 backwards is connected with the rear end wall of the gear transmission cavity 57, the tail end of the front side of the long gear shaft 25 is fixedly connected with a large gear 58 meshed with the small gear 65, the long gear shaft 25 is fixedly connected with a long gear 72 positioned in the long gear cavity 71, the long gear shaft 25 is fixedly connected with a driven bevel gear 51 positioned in the bevel gear transmission cavity 50, the right side of the sliding bevel gear cavity 48 is provided with a sliding small gear cavity 80, the right end wall of the bevel gear transmission cavity 50 is connected with a sliding bevel gear shaft 49 which extends through the sliding bevel gear cavity 48 to the sliding small gear cavity 80 rightwards in a rotating fit mode, and the tail end of the left side of the sliding bevel gear shaft 49 is fixedly connected with a driving bevel gear 52 meshed with the driven bevel gear 51.

In addition, in one embodiment, a sliding shaft sleeve 55 located in the sliding bevel gear cavity 48 is connected to the sliding bevel gear shaft 49 in a spline fit manner, a sliding shaft sleeve spring 53 is fixedly connected between the left end surface of the sliding shaft sleeve 55 and the left end wall of the sliding bevel gear cavity 48, a sliding bevel gear 54 is fixedly connected to the sliding shaft sleeve 55, a fan 59 located in the heating cavity 61 and located at the rear side of the heating pipe 60 is fixedly connected to the lower end of the fan shaft 22, a rear sliding cavity 15 is communicated between the sliding bevel gear cavity 48 and the drying cavity 14, a front sliding cavity 35 is communicated with the front side of the drying cavity 14, a sliding block cavity 34 is communicated with the front side of the front sliding cavity 35, a pulley transmission cavity 30 is arranged at the right side of the drying cavity 14, a driven pulley shaft 33 extending through the sliding block cavity 34 to the pulley transmission cavity 30 rightwards is connected to the left end wall of the sliding block cavity 34 in a rotation fit, the driven pulley shaft 33 is connected with a sliding block 36 in a threaded fit manner and connected with the sliding block cavity 34 in a sliding fit manner, the sliding block 36 is connected with a recovery shaft 37 in a rotating fit manner, the recovery shaft 37 extends backwards and penetrates through the front sliding cavity 35, the drying cavity 14 and the rear sliding cavity 15 to the sliding bevel gear cavity 48, and the tail end of the rear side of the recovery shaft 37 is fixedly connected with a recovery shaft bevel gear 56 meshed with the sliding bevel gear 54.

In addition, in one embodiment, the rear side of the sliding bevel gear cavity 48 is provided with a motor 26 fixedly connected with the main box 10, the right side of the motor 26 is provided with a transmission belt cavity 84, the right end face of the motor 26 is fixedly connected with a motor shaft 27 extending rightwards into the transmission belt cavity 84, the right end of the motor shaft 27 is fixedly connected with a motor pulley 73, the right end wall of the transmission belt cavity 84 is rotatably and fittingly connected with a transmission shaft 78 extending rightwards to penetrate through the sliding pinion cavity 80 to the right end wall of the sliding pinion cavity 80 and extending leftwards into the transmission belt cavity 84, the left end of the transmission shaft 78 is fixedly connected with a transmission shaft gear 82, a transmission belt 83 is connected between the transmission shaft gear 82 and the motor pulley 73 in a power fit manner, the transmission shaft 78 is fittingly and splined connected with a magnetic sliding shaft sleeve 75 positioned in the sliding pinion cavity 80, fixedly connected with is located on the transmission shaft 78 slide in the pinion cavity 80 and use magnetism slip axle sleeve 75 is central bilateral symmetry's electro-magnet 77, electro-magnet 77 with fixedly connected with magnet axle sleeve spring 76 between the magnetism slip axle sleeve 75, fixedly connected with slip pinion 74 on the magnetism slip axle sleeve 75, slip bevel gear axle 49 right side end fixedly connected with can with the left gear 81 of slip pinion 74 meshing.

In addition, in one embodiment, a driving pulley shaft 28 extending rightward into the pulley transmission chamber 30 and extending leftward into the sliding pinion chamber 80 is rotatably coupled to the right end wall of the sliding pinion chamber 80, a right gear 79 capable of meshing with the sliding pinion 74 is fixedly connected to the left end of the driving pulley shaft 28, a driving pulley 29 is fixedly connected to the right end of the driving pulley shaft 28, a driven pulley 32 is fixedly connected to the right end of the driven pulley shaft 33, a belt 31 is rotatably coupled between the driven pulley 32 and the driving pulley 29, and a recovery sleeve 85 located in the drying chamber 14 is fixedly connected to the recovery shaft 37.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

As shown in fig. 1-5, when the apparatus of the present invention is in an initial state, the left and right friction sliding blocks 18 move towards the side close to the fabric rotating shaft 41 under the elastic force of the friction block spring 46, so that the friction block 19 is attached to the outer circular surface of the fabric rotating shaft 41, the sliding shaft sleeve 55 moves rightwards under the elastic force of the sliding shaft sleeve spring 53 until being engaged with the recovery shaft bevel gear 56 all the time, the gear block rotating seat 21 moves backwards under the elastic force of the sliding gear spring 24, so that the rear end surface of the sliding gear 70 is flush with the rear end surface of the long gear 72, the electromagnet 77 is de-energized, so that the magnetic sliding shaft sleeve 75 is in the middle position of the sliding pinion cavity 80 under the elastic force of the left and right side magnet shaft sleeve springs 76, and the sliding pinion 74 is not engaged with the left gear 81 and; sequence of mechanical actions of the whole device: when the cloth drying machine starts to work, cloth to be dried is sleeved on the fabric rotating shaft 41 and abuts against the rear end face of the fixed baffle 42, the sliding baffle 16 abuts against the rear end face of the cloth, the fixed knob 43 is rotated, due to the threaded fit between the fixed knob 43 and the sliding baffle 16, the fixed knob 43 moves towards the direction close to the outer circular face of the fabric rotating shaft 41 to abut against the outer circular face of the fabric rotating shaft 41, the sliding baffle 16 cannot move under the left and right friction force between the fixed knob 43 and the outer circular face of the fabric rotating shaft 41, the cloth bypasses the upper side face of the drying rotating block 39 and is fixed on the lower side face of the recovery sleeve 85, the heating pipe 60 is started to start heating, so that the cloth which is initially contacted with the drying rotating block 39 is firstly dried, meanwhile, the motor 26 is started to drive the motor shaft 27 to rotate, thereby the motor belt wheel, thereby rotating the transmission shaft 78 to drive the magnetic sliding shaft sleeve 75 to rotate, thereby rotating the sliding pinion 74, and at this time, the right electromagnet 77 is electrified to attract the magnetic sliding shaft sleeve 75 to move rightwards against the elasticity of the right magnet shaft sleeve spring 76, thereby driving the sliding pinion 74 to move rightwards to be meshed with the right gear 79, the sliding pinion 74 rotates to drive the right gear 79 to rotate, thereby driving the driving pulley shaft 28 to rotate, thereby driving the driving pulley 29 to rotate, driving the driven pulley 32 to rotate through the belt 31, thereby driving the driven pulley shaft 33 to rotate, and due to the threaded fit between the driven pulley shaft 33 and the sliding block 36, the sliding block 36 moves rightwards, thereby driving the recovery shaft 37 to move rightwards, thereby driving the recovery sleeve 85 to move rightwards, thereby drying the cloth from the beginning end; meanwhile, the recovery shaft 37 drives the recovery shaft bevel gear 56 to move rightwards, due to the elastic force of the sliding shaft sleeve spring 53, the sliding bevel gear 54 is always meshed with the recovery shaft bevel gear 56, when the sliding block 36 moves rightwards until the right end face of the sliding block 36 is attached to the right end wall of the sliding block cavity 34, the right side electromagnet 77 is powered off, the left side electromagnet 77 is powered on, so that the sliding pinion 74 moves leftwards to be meshed with the left gear 81, the sliding pinion 74 rotates to drive the sliding bevel gear shaft 49 to rotate, so that the sliding shaft sleeve 55 rotates to drive the sliding bevel gear 54 to rotate, so that the recovery shaft 37 rotates to drive the recovery sleeve 85 to rotate to recover dried cloth, meanwhile, the sliding bevel gear shaft 49 rotates to drive the driving bevel gear 52 to rotate, so that the driven bevel gear 51 rotates to drive the long gear shaft 25 to rotate, so that the, thereby driving the pinion 65 to rotate reversely, thereby causing the rotating seat connecting shaft 67 to rotate reversely, thereby driving the drying rotating seat 12 to rotate reversely, thereby causing the drying rotating block 39 to rotate reversely, thereby causing the rotating direction of the drying rotating block 39 to be opposite to the cloth moving direction, thereby causing the relative position of the hot air through cavity 63 and the cloth to be changed all the time, thereby causing the hot air in the hot air through cavity 63 to be contacted with the whole cloth uniformly, and under the action of the friction force of the friction block 19, when the recycling sleeve 85 rotates to drive the fabric rotating shaft 41 to rotate through the cloth, the cloth can be tensioned, thereby causing the cloth to be tightly attached to the upper surface of the drying rotating block 39, thereby realizing that the device drying is thorough and uniform, and the gas generated by drying is discharged to the outside from the ventilation cavity 11; when the long gear shaft 25 rotates to drive the long gear 72 to rotate, so that the sliding gear 70 rotates to drive the fan shaft 22 to rotate, so that the fan 59 rotates to generate wind, the wind is changed into hot wind after passing through the heated heating pipe 60 and is blown out to contact with the cloth through the hot air through cavity 63, so that the drying of the wet cloth is accelerated, when small-size cloth needs to be dried, the fixing knob 43 is reversely rotated, so that the sliding baffle 16 can move forwards to be abutted against the rear end face of the lower-size cloth, the sliding baffle 16 cannot move freely in the forward rotation fixing knob 43, the baffle rotating seat 17 is driven to move forwards due to the forward movement of the sliding baffle 16, so that the pull rope 20 is pulled to enable the gear block rotating seat 21 to move forwards to overcome the elastic force of the sliding gear spring 24, so that the gear fixing block 69 is driven to move forwards, so that the sliding gear 70 moves forwards, so that the fan shaft 22 is, thereby make heating block 62 move forward, the steam that is located heating block 62 rear side leads to chamber 63 and does not have steam to pass through, is located heating block 62 front side and has steam to pass through, reduces the heat of heating pipe 60 this moment, and the rotational speed of motor 26 reduces, because the space of heating block sliding chamber 40 diminishes to make the heat stoving effect after reducing also general with before, thereby reached the effect that reduces the energy consumption when drying small-size cloth.

The invention has the beneficial effects that: utilize the rotatory steam of stoving to lead to the chamber with steam and cloth direct contact, make cloth stoving more quick, efficiency is higher, the rotatory piece rotation direction of drying simultaneously is opposite with cloth direction of motion, avoided the local long-time cloth of contact that does not have steam on the rotatory piece of stoving and lead to drying not thorough problem, the device is owing to heating block sliding chamber space reduces when drying small-size cloth simultaneously, make and reduce steam and also can guarantee the stoving effect, thereby the effect of reducing the energy consumption when having reached the small-size cloth of stoving.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a can be to energy-conserving drying device of not unidimensional surface fabric stoving, includes the main tank body, its characterized in that: a drying cavity is arranged in the main box body, the upper side of the drying cavity is communicated with a ventilation cavity, the rear side of the drying cavity is provided with a friction block sliding cavity, the rear end wall of the friction block sliding cavity is connected with a fabric rotating shaft which extends forwards and penetrates through the friction block sliding cavity and the drying cavity to the front end wall of the drying cavity in a rotating fit manner, the fabric rotating shaft is fixedly connected with a fixed baffle plate positioned in the drying cavity, a baffle plate rotating seat is arranged in the drying cavity, a sliding baffle plate cavity with a forward opening is arranged in the baffle plate rotating seat, the rear side of the sliding baffle plate cavity is communicated with a rotating shaft through cavity with a backward opening, the fabric rotating shaft penetrates through the rotating shaft through cavity, the sliding baffle plate cavity is connected with a sliding baffle plate in a rotating fit manner, and a fixed knob which can be abutted against the outer circular surface of the sliding baffle plate is connected, the friction block sliding cavity is connected with friction sliding blocks which are bilaterally symmetrical by taking the fabric rotating shaft as a center in a sliding fit manner, the friction sliding blocks are fixedly connected with the friction blocks which are abutted against the outer circular surface of the fabric rotating shaft by being close to the end surface of the fabric rotating shaft, the friction sliding blocks are far away from the end surface of the fabric rotating shaft and are fixedly connected with friction block springs which are bilaterally symmetrical by taking the fabric rotating shaft as the center between the end wall of the friction block sliding cavity and the end wall of the friction block sliding cavity, the rear end surface of the baffle rotating seat is fixedly connected with a pull rope, the rear side of the drying cavity is provided with a sliding gear cavity positioned at the right side of the friction block sliding cavity, the right side of the sliding gear cavity is communicated with a long gear cavity, the lower side of the sliding gear cavity is provided with a gear transmission, a bevel gear transmission cavity located on the right side of the connecting shaft cavity is arranged between the gear transmission cavity and the long gear cavity, and a sliding bevel gear cavity is arranged on the right side of the bevel gear transmission cavity.

2. The energy-saving drying device for drying the fabrics with different sizes as claimed in claim 1 is characterized in that: the drying rotary block comprises a connecting shaft cavity, a rotary seat connecting shaft, a drying rotary seat, a fan shaft through cavity, a rotary block sliding cavity, a heating block sliding cavity, a plurality of hot air through cavities and a heating block, wherein the rotary seat connecting shaft extends forwards into the drying cavity in a rotating fit mode, the front end face of the rotary seat connecting shaft is fixedly connected with the drying rotary seat, the fan shaft through cavity extends backwards through the rotary seat connecting shaft to an upward opening, the front side of the fan shaft through cavity is communicated with the rotary block rotating cavity with a forward opening, the drying rotary block rotating cavity is fixedly connected with the drying rotary block, the drying rotary block front end face is fixedly connected with the drying rotary shaft which extends forwards into the drying cavity front end wall and is in rotating fit connection with the drying cavity front end wall, the drying rotary block is internally provided with the heating block sliding cavity with a backward opening, the heating block sliding cavity is internally and externally provided with a plurality of hot air through cavities, the heating device is characterized in that a heating cavity with a forward opening is arranged in the heating block, a heating pipe is fixedly connected to the inner wall of the heating cavity, and the rear end wall of the heating cavity is connected with a fan shaft which extends forwards and backwards in the heating cavity and penetrates through the rotating block rotating cavity, the fan shaft penetrating cavity and the shaft connecting cavity to the sliding gear cavity.

3. The energy-saving drying device for drying the fabrics with different sizes as claimed in claim 2 is characterized in that: the tail end of the rear side of the fan shaft is fixedly connected with a sliding gear, the front end face of the sliding gear is fixedly connected with a gear fixing block which is connected with the fan shaft in a rotating matching way, the gear fixing block is connected with a gear block rotating seat in a rotating matching way, a fan shaft through cavity is arranged in the gear block rotating seat in a front-back through way, a sliding gear spring is fixedly connected between the front end face of the gear block rotating seat and the front end wall of the sliding gear cavity, the fan shaft penetrates through the fan shaft through cavity, the other end of the stay cord is fixedly connected with the front end face of the gear block rotating seat, a pinion gear positioned in the gear transmission cavity is fixedly connected on the rotating seat connecting shaft, a long gear shaft which extends through the bevel gear transmission cavity backwards to the long gear cavity is connected in a rotating matching way on the rear end wall of the gear transmission cavity, and a bull gear, the bevel gear transmission mechanism is characterized in that a long gear is fixedly connected to a long gear shaft and located in a long gear cavity, a driven bevel gear is fixedly connected to the long gear shaft and located in a bevel gear transmission cavity, a sliding pinion cavity is arranged on the right side of the sliding bevel gear cavity, a sliding bevel gear shaft which extends through the sliding bevel gear cavity to the sliding pinion cavity is connected to the right end wall of the bevel gear transmission cavity in a rotating fit mode, and a driving bevel gear meshed with the driven bevel gear is fixedly connected to the left end of the sliding bevel gear shaft in a tail-end fixing mode.

4. The energy-saving drying device capable of drying fabrics with different sizes according to claim 3 is characterized in that: the sliding bevel gear drying device is characterized in that a sliding shaft sleeve located in a sliding bevel gear cavity is connected to the sliding bevel gear shaft in a spline fit mode, a sliding shaft sleeve spring is fixedly connected between the left end face of the sliding shaft sleeve and the left end wall of the sliding bevel gear cavity, a sliding bevel gear is fixedly connected to the sliding shaft sleeve, the tail end of the lower side of the fan shaft is fixedly connected to a fan located in the heating cavity and located at the rear side of the heating pipe, a rear sliding cavity is communicated between the sliding bevel gear cavity and the drying cavity, a front sliding cavity is communicated with the front side of the drying cavity, a sliding block cavity is communicated with the front side of the front sliding cavity, a belt wheel transmission cavity is arranged on the right side of the drying cavity, a driven belt wheel shaft extending through the sliding block cavity to the belt wheel transmission cavity rightwards is connected to the left end wall of the sliding block cavity in a rotation fit mode, a sliding block connected The recovery shaft extends through the front sliding cavity, the drying cavity and the rear sliding cavity to the sliding bevel gear cavity, and the tail end of the rear side of the recovery shaft is fixedly connected with a recovery shaft bevel gear meshed with the sliding bevel gear.

5. The energy-saving drying device capable of drying fabrics with different sizes according to claim 4 is characterized in that: the rear side of the sliding bevel gear cavity is provided with a motor fixedly connected with the main box body, the right side of the motor is provided with a transmission belt cavity, the right end face of the motor is fixedly connected with a motor shaft which extends rightwards into the transmission belt cavity, the tail end of the right side of the motor shaft is fixedly connected with a motor belt wheel, the right end wall of the transmission belt cavity is rotationally and cooperatively connected with a transmission shaft which extends rightwards into the sliding pinion cavity and extends leftwards into the transmission belt cavity, the tail end of the left side of the transmission shaft is fixedly connected with a transmission shaft gear, a transmission belt is connected between the transmission shaft gear and the motor belt wheel in a power fit manner, the transmission shaft is in spline fit connection with a magnetic sliding shaft sleeve positioned in the sliding pinion cavity, and the transmission shaft is fixedly connected with electromagnets which are positioned in the sliding pinion cavity and are bilaterally symmetrical, the electromagnet and the magnetic sliding shaft sleeve are fixedly connected with a magnet shaft sleeve spring, the magnetic sliding shaft sleeve is fixedly connected with a sliding pinion, and the tail end of the right side of the sliding bevel gear shaft is fixedly connected with a left gear which can be meshed with the sliding pinion.

6. The energy-saving drying device capable of drying fabrics with different sizes according to claim 5 is characterized in that: the right end wall of the sliding pinion cavity is connected with a driving pulley shaft which extends rightwards into the pulley transmission cavity and leftwards into the sliding pinion cavity in a rotating fit mode, the left end of the driving pulley shaft is fixedly connected with a right gear which can be meshed with the sliding pinion, the right end of the driving pulley shaft is fixedly connected with a driving pulley, the right end of the driven pulley shaft is fixedly connected with a driven pulley, a belt is connected between the driven pulley and the driving pulley in a power fit mode, and a recovery sleeve located in the drying cavity is fixedly connected with a recovery shaft.

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