CN116479602A - Steam sealing energy-saving device of steaming box - Google Patents

Abstract

The invention relates to the technical field of steaming boxes, and particularly provides a steam sealing energy-saving device of a steaming box. This steam seal economizer of steam ager includes outer box, steam seal subassembly, conveying subassembly, two diffusion subassembly, two seal the fender subassemblies, the heating cavity that runs through to the bottom has been seted up at outer box top, steam seal subassembly fixed mounting is in the bottom of outer box, the feeding chamber has been seted up at steam seal subassembly top, enter into the feeding intracavity through reducing steam through the feeding clearance, and can drive the air in the feeding intracavity through the feeding clearance upward movement at the in-process that textile fabric constantly removed, can reduce steam and pass through the feeding clearance downward movement, the possibility that steam leaked has been reduced, can guide the flow of steam through the rising and the decline of flexible baffle, the practicality is improved, and can ensure the environment in the workshop, prevent dripping moisture in the workshop.

Description

Steam sealing energy-saving device of steaming box

Technical Field

The invention relates to the technical field of steaming boxes, in particular to a steam sealing energy-saving device of a steaming box.

Background

The steaming box is a laboratory device for heating and treating samples, the working principle is that steam is injected into a closed container to heat the samples and raise the temperature to required temperature, the device is generally used for drying, sterilizing, curing, heat treatment and other processes of substances, the steaming box is generally used for heating and drying in dyeing and finishing processes in textile industry, fabrics are required to be soaked in dye in the dyeing process, the dye is firmly attached to the fabrics through the heating and the steam treatment in the steaming box, and the finishing process can be used for carrying out post-treatment on the fabrics to improve the hand feeling and the appearance of the fabrics. At present, in actual production operation, saturated steam in a steaming box often overflows outwards along a cloth inlet seam, so that a part of steam is outwards emitted, and energy consumption is lost.

Disclosure of Invention

Based on this, it is necessary to provide a steam sealing energy-saving device of a steaming box, so as to solve at least one technical problem set forth in the above background art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the steam sealing energy-saving device of the steaming box comprises an outer box, a steam sealing assembly, a conveying assembly, two diffusion assemblies and two blocking assemblies, wherein a heating cavity penetrating to the bottom is formed in the top of the outer box, the steam sealing assembly is fixedly arranged at the bottom of the outer box, a feeding cavity is formed in the top of the steam sealing assembly, the conveying assembly is rotatably arranged at the top of the outer box and the bottom of the steam sealing assembly, the two diffusion assemblies are symmetrically arranged in the heating cavity and are used for diffusing heat in the heating cavity to the periphery, the two blocking assemblies are symmetrically arranged at the top of the feeding cavity, a feeding gap is formed between the two blocking assemblies, and the blocking assemblies are used for adjusting the size of the feeding gap and recovering the heat in the heating cavity;

the steam seal assembly comprises a semi-closed steam seal shell and a steam seal baffle, wherein the semi-closed steam seal shell consists of two end plates, a side plate and a bottom plate, the top of the semi-closed steam seal shell is fixedly arranged at the bottom of the outer box, the top of the steam seal baffle is fixedly arranged at the bottom of the outer box, the steam seal baffle is connected with the two end plates of the semi-closed steam seal shell, and a steam seal gap is formed between the bottom of the steam seal baffle and the bottom of the semi-closed steam seal shell.

In one embodiment, drainage sloping plates are formed on two sides of the bottom of the outer box, a plurality of drainage grooves are formed on one side, facing the heating cavity, of the drainage sloping plates, and heating plates are arranged on two side walls of the outer box in a penetrating mode.

In one embodiment, the conveying assembly comprises a feeding roller, a transmission motor and a feeding roller, wherein the feeding roller is rotatably installed at the bottom of the semi-closed steam seal shell and is positioned in the steam seal gap, the transmission motor is fixedly installed at the bottom of the semi-closed steam seal shell, the output end of the transmission motor is fixedly connected with one end of the feeding roller, the feeding roller is rotatably installed at the upper part of the heating cavity, and the feeding roller are sleeved with the same textile fabric.

In one embodiment, the diffusion assembly comprises two diffusion pieces and a plurality of inclined baffles, the two diffusion pieces are rotatably arranged in the heating cavity and are positioned on two sides of the textile fabric, the diffusion pieces comprise a rotating shaft and a plurality of fan blades, the rotating shaft is rotatably arranged on two side walls of the heating cavity, the plurality of fan blades are arranged on the side walls of the rotating shaft in an array mode, the plurality of inclined baffles are arranged at the bottom of the heating cavity in an array mode in two rows, each row of inclined baffles are symmetrically arranged on two sides of the textile fabric, and the distance between each inclined baffle and the textile fabric is gradually reduced along the vertical upward direction.

In one embodiment, the conveying assembly further comprises a driving belt wheel, two driven belt wheels, a first driving belt and a second driving belt, wherein the driving belt wheel is rotatably installed at the bottom of the semi-closed steam seal shell and is fixedly connected with one end, far away from the driving motor, of the feeding roller, the two driven belt wheels are rotatably installed on the side wall of the outer box and are fixedly connected with the end parts of the two rotating shafts respectively, the first driving belt wheel is sleeved on the driving belt wheel and one of the driven belt wheels, and the second driving belt wheel is sleeved on the two driven belt wheels.

In one embodiment, two seal keep off the subassembly and be located the both sides of textile fabric respectively, seal the subassembly and include the gland seal pivot, gland seal expansion plate, sliding plate and remove the draw-in lever, the both ends rotation of gland seal pivot is installed on two lateral walls of feed chamber, and gland seal pivot and textile fabric parallel arrangement, the feeding clearance is the clearance between two gland seal pivots, the one end fixed mounting of gland seal expansion plate is on the lateral wall of gland seal pivot, sliding vertical groove has all been seted up at the lateral wall top that semi-closed gland seal shell and gland seal baffle face each other, and two sliding vertical grooves communicate each other with the feed chamber, sliding plate fixed mounting keeps away from the one end of textile fabric in gland seal expansion plate, and sliding plate slides and set up in sliding vertical groove, the removal draw-in groove has all been seted up at the top of semi-closed gland seal shell and gland seal baffle, and removal draw-in groove communicates each other with sliding vertical groove, remove the draw-in lever fixed mounting is on a lateral wall that the gland seal expansion plate kept away from, and removal draw-in lever sliding card locates in the removal draw-in groove, the axis of gland seal pivot is higher than the axis of removal draw-in lever.

In one embodiment, the top of the semi-closed steam seal shell and the top of the steam seal baffle are provided with a containing groove, the top of the containing groove is communicated with the movable clamping groove, a plurality of longitudinal telescopic springs are fixedly arranged at the bottom of the containing groove, the top of the plurality of longitudinal telescopic springs is fixedly provided with the same telescopic baffle, and the telescopic baffle is arranged in the movable clamping groove and the containing groove in a sliding mode.

In one embodiment, a plurality of tube grooves, water storage grooves, a plurality of drainage grooves and a plurality of linkage vertical grooves are formed in the tops of the semi-closed steam seal shell and the steam seal baffle, the shaft ends of the tube grooves are mutually communicated with one side of the movable clamping groove, one side of the water storage groove is mutually communicated with one side of the bottom of the movable clamping groove, the water storage groove is vertically arranged with the movable clamping groove, the end parts of the drainage grooves are mutually communicated with one side of the bottom of the water storage groove, the through tubes of the drainage grooves penetrate through the outer side wall of the semi-closed steam seal shell or the steam seal baffle, an L-shaped guide plate is fixedly arranged on the outer side wall of the semi-closed steam seal shell and the steam seal baffle, the bottoms of the linkage vertical grooves are mutually communicated with the tops of the movable clamping groove, memory alloy is fixedly arranged at the tops of the linkage vertical grooves, the memory alloy is folded, and the bottoms of the memory alloy are fixedly arranged to support the guide blocks, and the bottoms of the support guide blocks are supported on the movable clamping rods.

In one embodiment, a plurality of steam pipes are fixedly arranged on the outer side walls of the semi-closed steam enclosure and the steam sealing baffle, the steam pipes correspond to the pipe grooves, the pipe grooves are communicated with the steam pipes, and a water stop plate is convexly arranged at the bottom of one end, close to the pipe grooves, of the steam pipes.

In one embodiment, the side wall of the steam seal rotating shaft is convexly provided with steam seal convex blocks, and the steam seal convex blocks of the two steam seal rotating shafts are symmetrically arranged.

Compared with the prior art, the invention has the beneficial effects that:

1. when the steam in the outer box is less, the diffusion wind can drive the steam to further upwards move so that most of the steam upwards moves, only part of the steam can downwards move, when the steam in the outer box is more, the steam which upwards moves is discharged, the steam can be further dispersed on the side wall of the drainage inclined plate and the side wall of the inclined baffle under the action of the diffusion wind, and the inclined baffle can prevent part of the steam from directly entering the feeding cavity through the feeding gap during diffusion, so that the steam can be effectively reduced to enter the feeding cavity, the condition that excessive steam enters the feeding cavity and then overflows from the steam seal gap can be reduced, and the steam overflows from the steam seal gap.

2. When the continuous high temperature in the heating cavity causes too much steam, a large amount of steam flows and gathers in the feeding cavity through the feeding gap, and when too much steam in the feeding cavity overflows into the workshop from the steam seal gap, water drops formed in the workshop become wet, and the steam is also wasted, and the scheme can reduce the occurrence of the above conditions, so that the energy-saving effect is greatly improved, the steam flowing into the steam conduit can be recycled, the water discharged into the guide plate can be recycled, the waste of energy sources can be reduced, and the effect of environmental protection is achieved.

3. When opening a plurality of tube bank, a large amount of steam can enter into the steam conduit through the tube bank to reduce steam and enter into the feeding intracavity through the feeding clearance, and can drive the air in the feeding intracavity and pass through the feeding clearance and reciprocate at the in-process that textile fabric constantly removes, can reduce steam and pass through the feeding clearance and reciprocate, reduced the possibility that steam leaked, can guide the flow of steam through the rising and the decline of flexible baffle, improved the practicality, and can ensure the environment in the workshop, prevent in the workshop drip moist.

4. When two vapor seal lugs all move towards the direction of textile fabric, can reduce the feeding clearance, reduce the possibility that steam flows downwards through the feeding clearance, prevent that steam from passing through the feeding clearance and leading to the condition emergence of leaking through vapor seal clearance.

5. When the temperature and the steam in the heating cavity are not enough, the steam and the heat flow into the pipe groove, so that the temperature and the steam in the heating cavity can be automatically adjusted, the heating efficiency is improved, manual intervention and adjustment are not needed, the production efficiency is improved, the energy waste is avoided, and the production cost is reduced.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic cross-sectional view of the present invention drawn from fig. 1.

Fig. 3 is a schematic view of a partial enlarged structure at a in fig. 2.

Fig. 4 is a partially enlarged schematic structural view at B in fig. 2.

In the figure:

10. an outer case; 20. a vapor seal assembly; 30. a transfer assembly; 40. a diffusion assembly; 50. a blocking assembly; 11. heating the cavity; 21. a feed chamber; 511. a feed gap; 22. a semi-closed vapor enclosure; 23. a vapor seal baffle; 311. a vapor seal gap; 12. a drainage sloping plate; 121. drainage grooves; 13. a heating plate; 31. a feed roller; 32. a drive motor; 33. a feed roller; 100. weaving cloth; 41. a diffuser; 42. a tilting baffle; 411. a rotating shaft; 412. a fan blade; 34. a driving pulley; 35. a driven pulley; 36. a first belt; 37. a second belt; 51. a steam seal rotating shaft; 52. a gland sealing expansion plate; 53. a sliding plate; 54. moving the clamping rod; 211. sliding vertical grooves; 212. a movable clamping groove; 213. a receiving groove; 55. a telescopic spring; 56. a telescopic baffle; 214. a tube groove; 215. a water storage tank; 216. a drainage channel; 217. a linkage vertical groove; 24. a deflector; 218. a memory alloy; 219. a supporting guide block; 25. a steam conduit; 251. a water-stop plate; 512. and a steam seal lug.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

The invention provides a steam sealing energy-saving device of a steam box, which is shown in fig. 1-4, and comprises an outer box 10, a steam sealing assembly 20, a conveying assembly 30, two diffusion assemblies 40 and two blocking assemblies 50, wherein a heating cavity 11 penetrating to the bottom is formed at the top of the outer box 10, the steam sealing assembly 20 is fixedly arranged at the bottom of the outer box 10, a feeding cavity 21 is formed at the top of the steam sealing assembly 20, the conveying assembly 30 is rotatably arranged at the top of the outer box 10 and the bottom of the steam sealing assembly 20, the two diffusion assemblies 40 are symmetrically arranged in the heating cavity 11, the diffusion assemblies 40 are used for diffusing heat in the heating cavity 11 to the periphery, the two blocking assemblies 50 are symmetrically arranged at the top of the feeding cavity 21, a feeding gap 511 is formed between the two blocking assemblies 50, and the blocking assemblies 50 are used for adjusting the size of the feeding gap 511 and the heat emission in the heating cavity 11;

the steam seal assembly 20 comprises a semi-closed steam seal shell 22 and a steam seal baffle 23, wherein the semi-closed steam seal shell 22 consists of two end plates, a side plate and a bottom plate, the top of the semi-closed steam seal shell 22 is fixedly arranged at the bottom of the outer box 10, the top of the steam seal baffle 23 is fixedly arranged at the bottom of the outer box 10, the steam seal baffle 23 is connected with the two end plates of the semi-closed steam seal shell 22, and a steam seal gap 311 is formed between the bottom of the steam seal baffle 23 and the bottom of the semi-closed steam seal shell 22.

Both sides of the bottom of the outer box 10 are respectively provided with a drainage inclined plate 12, one side of the drainage inclined plate 12 facing the heating cavity 11 is provided with a plurality of drainage grooves 121, and both side walls of the outer box 10 are respectively provided with a heating plate 13 in a penetrating way.

The conveying assembly 30 comprises a feeding roller 31, a transmission motor 32 and a feeding roller 33, wherein the feeding roller 31 is rotatably arranged at the bottom of the semi-closed steam seal shell 22 and is positioned in a steam seal gap 311, the transmission motor 32 is fixedly arranged at the bottom of the semi-closed steam seal shell 22, the output end of the transmission motor 32 is fixedly connected with one end of the feeding roller 31, the feeding roller 33 is rotatably arranged at the upper part of the heating cavity 11, and the feeding roller 31 and the feeding roller 33 are sleeved with the same textile fabric 100.

The diffusion component 40 comprises two diffusion members 41 and a plurality of inclined baffles 42, the two diffusion members 41 are rotatably installed in the heating cavity 11 and are positioned on two sides of the textile fabric 100, the diffusion members 41 comprise a rotating shaft 411 and a plurality of fan blades 412, the rotating shaft 411 is rotatably installed on two side walls of the heating cavity 11, the plurality of fan blades 412 are equidistantly arranged on the side walls of the rotating shaft 411, the plurality of inclined baffles 42 are equidistantly arranged at the bottom of the heating cavity 11 in two rows, each row of inclined baffles 42 are symmetrically arranged on two sides of the textile fabric 100, and the distance between each inclined baffle 42 and the textile fabric 100 is gradually reduced along the vertical upward direction.

The conveying assembly 30 further comprises a driving belt pulley 34, two driven belt pulleys 35, a first driving belt 36 and a second driving belt 37, wherein the driving belt pulley 34 is rotatably installed at the bottom of the semi-closed steam seal shell 22 and fixedly connected with one end, far away from the driving motor 32, of the feeding roller 31, the two driven belt pulleys 35 are rotatably installed on the side wall of the outer box 10 and fixedly connected with the end parts of the two rotating shafts 411 respectively, the first driving belt 36 is sleeved on the driving belt pulley 34 and one of the driven belt pulleys 35, and the second driving belt 37 is sleeved on the two driven belt pulleys 35.

The two sealing components 50 are respectively located at two sides of the textile fabric 100, the sealing components 50 comprise a steam seal rotating shaft 51, a steam seal expansion plate 52, a sliding plate 53 and a movable clamping rod 54, two ends of the steam seal rotating shaft 51 are rotatably arranged on two side walls of a feeding cavity 21, the steam seal rotating shaft 51 and the textile fabric 100 are arranged in parallel, a feeding gap 511 is a gap between the two steam seal rotating shafts 51, one end of the steam seal expansion plate 52 is fixedly arranged on one side wall of the steam seal rotating shaft 51, sliding vertical grooves 211 are respectively formed in the tops of the side walls, facing each other, of the semi-closed steam seal shell 22 and the steam seal baffle 23, the two sliding vertical grooves 211 are mutually communicated with the feeding cavity 21, the sliding plate 53 is fixedly arranged at one end, far away from the textile fabric 100, of the steam seal expansion plate 52, the sliding plate 53 is slidably arranged in the sliding vertical grooves 211, the top of the semi-closed steam seal shell 22 and the steam seal baffle 23 is provided with movable clamping grooves 212, the movable clamping rod 54 is fixedly arranged on one side wall, far away from the expansion plate 52, and the movable clamping rod 54 is slidably arranged in the central axis 54 of the steam seal expansion plate 52.

The top of the semi-closed steam seal shell 22 and the top of the steam seal baffle 23 are provided with a containing groove 213, the top of the containing groove 213 is communicated with the movable clamping groove 212, a plurality of longitudinal telescopic springs 55 are fixedly arranged at the bottom of the containing groove 213, the top of the plurality of longitudinal telescopic springs 55 is fixedly provided with the same telescopic baffle 56, and the telescopic baffle 56 is arranged in the movable clamping groove 212 and the containing groove 213 in a sliding manner.

The semi-closed steam seal shell 22 and the top of the steam seal baffle 23 are respectively provided with a plurality of pipe grooves 214, a water storage groove 215, a plurality of water drainage grooves 216 and a plurality of linkage vertical grooves 217, the shaft ends of the plurality of pipe grooves 214 are mutually communicated with one side of the movable clamping groove 212, one side of the water storage groove 215 is mutually communicated with one side of the bottom of the movable clamping groove 212, the water storage groove 215 is vertically arranged with the movable clamping groove 212, the end parts of the plurality of water drainage grooves 216 are mutually communicated with one side of the bottom of the water storage groove 215, the through pipes of the water drainage grooves 216 are connected to the outer side wall of the semi-closed steam seal shell 22 or the steam seal baffle 23, the outer side walls of the semi-closed steam seal shell 22 and the steam seal baffle 23 are respectively fixedly provided with an L-shaped guide plate 24, the bottoms of the plurality of linkage vertical grooves 217 are mutually communicated with the top of the movable clamping groove 212, the tops of the linkage vertical grooves 217 are fixedly provided with a memory alloy 218, the bottoms of the memory alloy 218 are folded, the bottoms of the memory alloy 218 are fixedly arranged and propped against the guide block 219, and the bottoms of the propped against the guide block 219 are propped against the movable clamping rod 54.

A plurality of steam guide pipes 25 are fixedly arranged on the outer side walls of the semi-closed steam seal shell 22 and the steam seal baffle plate 23, a plurality of steam guide pipes correspond to a plurality of pipe grooves 214, the pipe grooves 214 are communicated with the steam guide pipes 25, and a water stop plate 251 is convexly arranged at the bottom of one end, close to the pipe grooves 214, of the steam guide pipes 25.

The side wall of the steam seal rotating shaft 51 is convexly provided with steam seal convex blocks 512, and the steam seal convex blocks 512 of the two steam seal rotating shafts 51 are symmetrically arranged.

In an embodiment, the steaming box can drive the textile fabric 100 to enter the steaming box at a constant speed, the textile fabric 100 can pass through the outer box 10 and the steam seal assembly 20 before entering the steaming box, and the conveying of the textile fabric 100 is assisted by the feeding roller 31 and the feeding roller 33, in order to ensure the stable conveying of the textile fabric 100, a transmission motor 32 is arranged at one end of the feeding roller 31, the transmission motor 32 drives the feeding roller 31 to rotate at a constant speed, the feeding roller 31 drives the textile fabric 100 to move at a constant speed, the speed at which the feeding roller 31 drives the textile fabric 100 to move is equal to or slightly less than the speed at which the textile fabric 100 enters the steaming box at a constant speed, so that the textile fabric 100 is in a straightened state, the surface of the feeding roller 31 is smooth, the friction force between the feeding roller 31 and the textile fabric 100 can be reduced, the friction force between the feeding roller 31 can be reduced, the situation that the textile fabric 100 is broken or torn due to too large friction force between the feeding roller 31 is prevented, the two side walls of the outer box 10 are also provided with the textile fabric 13, the heating plate 13 can heat the textile fabric 100, and the textile fabric 100 can be firmly attached to the fabric 100, and the fabric can be heated, and the fabric can be firmly attached to the fabric 100.

The feed roller 31 can drive the driving pulley 34 and rotate when rotating, the driving pulley 34 can drive one of them driven pulley 35 and rotate through first drive belt 36 when rotating, one of them driven pulley 35 can drive another driven pulley 35 and rotate through the second drive belt 37 when rotating, can drive two driven pulleys 35 and rotate when driving pulley 34, can drive two axis of rotation 411 when rotating two driven pulleys 35, axis of rotation 411 rotates and can drive a plurality of flabellum 412 on the axis of rotation 411 and rotate, a plurality of flabellum 412 rotates and can produce the diffusion wind that spreads all around axis of rotation 411, can produce steam when heating plate 13 heats, when steam in the outer tank 10 is less, the diffusion wind can drive steam further upwards to move so that most steam upwards moves, only part steam can move downwards, when the steam in the outer tank 10 is more, go out the steam that upwards moves, steam can also disperse on the lateral wall of drainage 12 and inclined baffle 42 under the effect of diffusion wind, the inclined baffle 42 can prevent that part of diffusion wind from entering into the gap 311 from the gap 21 is followed to the gap 311 directly, can prevent that steam from overflowing into the feed gap 21 from the gap 311, then can prevent that steam from overflowing into the feed gap 21.

In another embodiment, the height of the steam sealing baffle 23 is 60cm, the steam box is in 1.5 atmospheres, and steam cannot escape from the steam sealing gap 311 of the steam sealing assembly 20, so that the problem that the water drops seriously in a workshop due to the leakage of steam can be solved.

In an embodiment, when a large amount of steam adheres to the side walls of the drainage inclined plate 12 and the inclined baffle 42, water drops are slowly formed on the drainage inclined plate 12 and the inclined baffle 42, the water drops slowly gather in the drainage groove 121 on the drainage inclined plate 12 and flow downwards, the water drops on the inclined baffle 42 also flow downwards through the inclined plane of the inclined baffle 42, so that the water drops finally gather to the gland expansion plate 52, the central axis of the gland rotating shaft 51 is higher than the central axis of the moving clamping rod 54, so that the gland expansion plate 52 is obliquely arranged at a certain angle, when the water drops continuously gather on the gland expansion plate 52, the weight of the gland expansion plate 52 is continuously increased, when the weight of the gland expansion plate 52 is increased, one end of the gland expansion plate 52 away from the gland rotating shaft 51 moves downwards, and when one end of the gland expansion plate 52 away from the gland rotating shaft 51 moves downwards, the sliding plate 53 and the moving clamping rod 54 can be driven to move downwards, when the sliding plate 53 and the moving clamping rod 54 move downwards, steam can run to the upper parts of the sliding plate 53 and the moving clamping rod 54, the heat of the steam can enable the plurality of propping guide blocks 219 to heat up rapidly, the temperature of the propping guide blocks 219 can enable the memory alloy 218 to heat up rapidly, the temperature of the plurality of memory alloy 218 can slowly straighten downwards, the plurality of memory alloy 218 straighten downwards respectively drive the plurality of propping guide blocks 219 to move downwards, when the plurality of propping guide blocks 219 move downwards, the moving clamping rod 54 can be driven to move downwards, the moving clamping rod 54 can drive the telescopic baffle plate 56 to move downwards, the telescopic baffle plate 56 can compress the longitudinal telescopic spring 55, when the telescopic baffle plate 56 moves downwards, the plurality of pipe grooves 214 can not be closed, the steam can flow into the steam guide pipe 25 through the plurality of pipe grooves 214, the water collected on the gland expansion plate 52 can flow into the water storage tank 215 through the downward movement of the expansion baffle 56 and flow into the guide plate 24 through the water drainage tank 216 to be discharged, when the steam is too much due to the continuous high temperature in the heating cavity 11, a large amount of steam flows and collects in the feeding cavity 21 through the feeding gap 511, when too much steam in the feeding cavity 21 overflows into the workshop from the gland gap 311, water drops formed in the workshop become moist and the steam is wasted, the occurrence of the situations can be reduced, the energy saving effect is greatly improved, the steam flowing into the steam guide pipe 25 can be recycled, the water discharged into the guide plate 24 can be reused, the energy waste can be reduced, and the environmental protection effect is achieved.

In another embodiment, when the high temperature is continuously maintained so that more steam is formed in the heating cavity 11, the temperature in the heating cavity 11 is higher than the temperature in the feeding cavity 21, the pressure in the heating cavity 11 is higher than the pressure in the feeding cavity 21, downward moving pressure is formed on the gland expansion plate 52, the gland expansion plate 52 slightly turns downwards, the turning of the gland expansion plate 52 can drive the sliding plate 53 to move downwards, the downward moving of the sliding plate 53 can drive the moving clamping rod 54 to move downwards, the downward moving of the moving clamping rod 54 can enable steam to pass through the sliding vertical groove 211 and the top of the moving clamping groove 212, the abutting guide block 219 is enabled to be contacted with the steam to be quickly heated, the abutting guide block 219 is enabled to be quickly heated, the memory alloy 218 is enabled to be straightened when the temperature of the memory alloy 218 is raised, the downward straightening of the plurality of the memory alloy 218 can respectively drive the abutting guide blocks 219 to move downwards, the plurality of supporting guide blocks 219 can drive the movable clamping rods 54 to move downwards when moving downwards, the movable clamping rods 54 can drive the telescopic baffle plates 56 to move downwards, the telescopic baffle plates 56 can compress the longitudinal telescopic springs 55 when moving downwards, the plurality of pipe grooves 214 can not be closed when moving downwards, steam can flow into the steam guide pipes 25 through the plurality of pipe grooves 214, when the telescopic baffle plates 56 move downwards to open the plurality of pipe grooves 214, the pressure can be relieved through the plurality of pipe grooves 214, so that the steam flows into the steam guide pipes 25 towards the direction of the pipe grooves 214, when the plurality of pipe grooves 214 are opened, a large amount of steam can enter the steam guide pipes 25 through the pipe grooves 214, so that the steam is reduced to enter the feeding cavity 21 through the feeding gaps 511, and the air in the feeding cavity 21 can be driven to move upwards through the feeding gaps 511 in the continuous moving process of the textile cloth 100, can reduce steam and pass through feed gap 511 and remove downwards, reduce the possibility that steam leaked, can guide the flow of steam through the rising and the decline of flexible baffle 56, improve the practicality, and can ensure the environment in the workshop, prevent that the workshop from dripping the moisture.

In another embodiment, the same steam recovery pipeline is installed at one end of the plurality of steam conduits 25 far away from the steam sealing assembly 20, so that steam discharged into the steam conduits 25 can be recovered and utilized, waste of energy sources is reduced, water flow collecting boxes are installed at two ends of the guide plates 24, water flows flowing into the guide plates 24 are collected and recovered, water source waste is prevented, the recovery utilization rate of the energy sources is improved, and the environment-friendly and energy-saving effects are achieved.

In an embodiment, a gland lug 512 is convexly arranged on the side wall of the gland rotary shaft 51, when the temperature in the heating cavity 11 is too high to enable the gland expansion plate 52 to overturn downwards, the gland expansion plate 52 can drive the gland rotary shaft 51 to rotate, the gland rotary shaft 51 can drive the gland lug 512 to move towards the direction close to the textile fabric 100, when the two gland lugs 512 move towards the textile fabric 100, the feeding gap 511 can be reduced, the possibility that steam flows downwards through the feeding gap 511 is reduced, and the occurrence of leakage caused by the steam passing through the feeding gap 511 and the gland gap 311 is prevented.

In one embodiment, when the temperature in the heating cavity 11 is reduced, the water drops formed by the steam continuously gather into fine water flows when the temperature in the heating cavity 11 is reduced and the water flows to the water storage tank 215 through the gland expansion plate 52, the water flows to the abutting guide block 219, in order to ensure that the water flows in the direction of the steam conduit 25, the bottom of one end of the steam conduit 25, which is close to the outer box 10, is further provided with a water baffle 251, the water baffle 251 can prevent the water flow from flowing into the steam conduit 25, the water flows can take away the heat of the abutting guide block 219 when the water flows through the abutting guide block 219, so that the temperature of the abutting guide block 219 is reduced, the temperature of the memory alloy 218 is reduced, the abutting guide block 219 is contracted when the temperature of the memory alloy 218 is reduced, so that the abutting guide block 219 moves upwards, when the supporting guide block 219 moves upwards, the telescopic baffle 56 can move upwards under the action of the elastic force of the longitudinal telescopic spring 55, the upward movement of the telescopic baffle 56 can drive the movable clamping rod 54 and the sliding plate 53 to move upwards, the upward movement of the movable clamping rod 54 and the sliding plate 53 can enable the vapor seal telescopic plate 52 to turn upwards and reset, when the telescopic baffle 56 moves upwards and resets, the plurality of tube slots 214 can be reclosed, so that steam and heat are stored in the heating cavity 11, when the temperature and the steam in the heating cavity 11 are insufficient, the steam and the heat can flow into the tube slots 214, the temperature and the steam in the heating cavity 11 can be ensured to be at a proper temperature and steam density, the heating efficiency can be automatically adjusted, the manual intervention adjustment is not needed, the production efficiency is improved, the energy waste is avoided, the production cost is reduced.

During installation, the top of the semi-closed steam seal shell 22 is fixedly installed at the bottom of the outer box 10, the top of the steam seal baffle 23 is fixedly installed at the bottom of the outer box 10, the feeding roller 31 is rotatably installed at the bottom of the semi-closed steam seal shell 22, the transmission motor 32 is fixedly installed at the bottom of the semi-closed steam seal shell 22, the feeding roller 33 is rotatably installed at the upper part of the heating cavity 11, the two diffusion pieces 41 are rotatably installed in the heating cavity 11, the rotating shaft 411 is rotatably installed on two side walls of the heating cavity 11, the plurality of fan blades 412 are equidistantly arranged on the side wall of the rotating shaft 411, the plurality of inclined baffles 42 are equidistantly arranged at the bottom of the heating cavity 11 in two rows, the driving pulley 34 is rotatably installed at the bottom of the semi-closed steam seal shell 22, the two driven pulleys 35 are rotatably installed on the side wall of the outer box 10, two ends of the steam seal rotating shaft 51 are rotatably installed on two side walls of the feeding cavity 21, one end of the steam seal expansion plate 52 is fixedly installed on the side wall of the steam seal rotating shaft 51, the sliding plate 53 is fixedly installed at one end of the expansion plate 52 far away from the textile fabric 100, the plurality of inclined baffles 42 are fixedly installed at the bottom of expansion springs 55 are fixedly installed at the bottom of the expansion springs 213, and the expansion springs 55 are fixedly installed at the top of the expansion springs 55 are fixedly installed at the bottom of the expansion springs 213.

The guide plate 24 is fixedly arranged on the outer side wall of the semi-closed steam seal shell 22 or the steam seal baffle plate 23, the memory alloy 218 is fixedly arranged on the top of the linkage vertical groove 217, the supporting guide block 219 is fixedly arranged at the bottom of the memory alloy 218, the steam guide pipes 25 are fixedly arranged on the outer side walls of the semi-closed steam seal shell 22 and the steam seal baffle plate 23, the water baffle plate 251 is fixedly arranged at the bottom of one end, close to the pipe groove 214, of the steam guide pipe 25, and the steam seal protruding block 512 is fixedly arranged on the side wall of the steam seal rotating shaft 51.

The beneficial effects are that:

1. when the steam in the outer box 10 is less, the diffusion wind can drive the steam to further upwards move so that most of the steam upwards moves, only part of the steam can downwards move, when the steam in the outer box 10 is more, the steam which upwards moves is discharged, the steam can be further dispersed on the side walls of the drainage inclined plate 12 and the inclined baffle 42 under the action of the diffusion wind, and the inclined baffle 42 can prevent part of the steam from entering the feeding cavity 21 through the feeding gap 511 when being diffused, so that the steam can be effectively reduced from entering the feeding cavity 21, the situation that the excessive steam overflows from the steam seal gap 311 after entering the feeding cavity 21 can be prevented, and the overflow of the steam from the steam seal gap 311 can be reduced.

2. When the steam is too much due to the continuous high temperature in the heating cavity 11, a large amount of steam flows and gathers in the feeding cavity 21 through the feeding gap 511, and when the steam in the feeding cavity 21 is too much, the steam overflows into the workshop from the steam seal gap 311, so that water drops formed in the workshop become wet, the steam is also wasted, the occurrence of the above situations can be reduced, the energy-saving effect is greatly improved, the steam flowing into the steam conduit 25 can be recycled, the water discharged to the guide plate 24 can be reused, the waste of energy sources can be reduced, and the environmental protection effect is achieved.

3. When opening a plurality of tube groove 214, a large amount of steam can enter into steam conduit 25 through tube groove 214 to reduce steam and enter into feed cavity 21 through feeding clearance 511, and can drive the air in the feed cavity 21 and upwards move through feeding clearance 511 at the in-process that textile fabric 100 constantly removed, can reduce steam and move downwards through feeding clearance 511, reduced the possibility that steam leaked, can guide the flow of steam through the rising and the decline of flexible baffle 56, improved the practicality, and can ensure the environment in the workshop, prevent in the workshop drip moist.

4. When both the steam seal protrusions 512 move in the direction of the textile fabric 100, the feeding gap 511 can be reduced, the possibility that steam flows downwards through the feeding gap 511 is reduced, and the steam is prevented from leaking through the steam seal gap 311 due to the steam passing through the feeding gap 511.

5. Can prevent when temperature and steam in heating cavity 11 are not enough, steam and heat still flow to tube groove 214, can guarantee to be in a suitable temperature and steam density in the heating cavity 11, can automatically regulated heating cavity 11 in temperature and steam, improve the efficiency of heating, need not the manual work and intervene the regulation, improved production efficiency, avoided the energy extravagant, reduced manufacturing cost.

All possible combinations of the technical features in the above embodiments are described, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above embodiments represent only a few embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the present invention. It should be noted that numerous variations and modifications could be made to the person skilled in the art without departing from the spirit of the invention, which would fall within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (10)

1. The steam sealing energy-saving device of the steaming box is characterized by comprising an outer box (10), a steam sealing assembly (20), a conveying assembly (30), two diffusion assemblies (40) and two blocking assemblies (50), wherein a heating cavity (11) penetrating to the bottom is formed in the top of the outer box (10), the steam sealing assembly (20) is fixedly arranged at the bottom of the outer box (10), a feeding cavity (21) is formed in the top of the steam sealing assembly (20), the conveying assembly (30) is rotatably arranged at the top of the outer box (10) and the bottom of the steam sealing assembly (20), the two diffusion assemblies (40) are symmetrically arranged in the heating cavity (11), the diffusion assemblies (40) are used for diffusing heat in the heating cavity (11) to the periphery, the two blocking assemblies (50) are symmetrically arranged at the top of the feeding cavity (21), a feeding gap (511) is formed between the two blocking assemblies (50), and the blocking assemblies (50) are used for adjusting the size of the feeding gap (511) and recovering heat in the heating cavity (11); the steam seal assembly (20) comprises a semi-closed steam seal shell (22) and a steam seal baffle (23), wherein the semi-closed steam seal shell (22) consists of two end plates, a side plate and a bottom plate, the top of the semi-closed steam seal shell (22) is fixedly arranged at the bottom of the outer box (10), the top of the steam seal baffle (23) is fixedly arranged at the bottom of the outer box (10), the steam seal baffle (23) is connected with the two end plates of the semi-closed steam seal shell (22), and a steam seal gap (311) is formed between the bottom of the steam seal baffle (23) and the bottom of the semi-closed steam seal shell (22).

2. The steam sealing energy-saving device of a steaming box according to claim 1, wherein both sides of the bottom of the outer box (10) are respectively provided with a drainage inclined plate (12), one side of the drainage inclined plate (12) facing the heating cavity (11) is provided with a plurality of drainage grooves (121), and both side walls of the outer box (10) are respectively provided with a heating plate (13) in a penetrating way.

3. The steam sealing energy-saving device of a steam box according to claim 2, wherein the conveying assembly (30) comprises a feeding roller (31), a transmission motor (32) and a feeding roller (33), the feeding roller (31) is rotatably arranged at the bottom of the semi-closed steam sealing shell (22) and is positioned in a steam sealing gap (311), the transmission motor (32) is fixedly arranged at the bottom of the semi-closed steam sealing shell (22), the output end of the transmission motor (32) is fixedly connected with one end of the feeding roller (31), the feeding roller (33) is rotatably arranged at the upper part of the heating cavity (11), and the feeding roller (31) and the feeding roller (33) are sleeved with the same textile fabric (100).

4. A steam sealing energy saving device for a steaming box according to claim 3, wherein the diffusion assembly (40) comprises two diffusion members (41) and a plurality of inclined baffles (42), the two diffusion members (41) are rotatably mounted in the heating cavity (11) and are positioned at two sides of the textile fabric (100), the diffusion members (41) comprise a rotating shaft (411) and a plurality of fan blades (412), the rotating shaft (411) is rotatably mounted on two side walls of the heating cavity (11), the plurality of fan blades (412) are equidistantly arranged on the side walls of the rotating shaft (411), the plurality of inclined baffles (42) are mounted at the bottom of the heating cavity (11) in two rows of equidistant arrays, each row of inclined baffles (42) are symmetrically arranged at two sides of the textile fabric (100), and the distance between each inclined baffle (42) and the textile fabric (100) is gradually reduced along the vertical upward direction.

5. The steam seal energy-saving device of a steam box according to claim 4, wherein the conveying assembly (30) further comprises a driving pulley (34), two driven pulleys (35), a first driving belt (36) and a second driving belt (37), the driving pulley (34) is rotatably mounted at the bottom of the semi-closed steam seal shell (22) and fixedly connected with one end, far away from the driving motor (32), of the feeding roller (31), the two driven pulleys (35) are rotatably mounted on the side wall of the outer box (10) and fixedly connected with the end parts of the two rotating shafts (411), the first driving belt (36) is sleeved on the driving pulley (34) and one of the driven pulleys (35), and the second driving belt (37) is sleeved on the two driven pulleys (35).

6. The steam sealing energy-saving device of a steam box according to claim 5, wherein the two sealing components (50) are respectively positioned at two sides of the textile fabric (100), the sealing components (50) comprise a steam sealing rotating shaft (51), a steam sealing expansion plate (52), sliding plates (53) and a movable clamping rod (54), two ends of the steam sealing rotating shaft (51) are rotatably arranged on two side walls of the feeding cavity (21), the steam sealing rotating shaft (51) and the textile fabric (100) are arranged in parallel, a feeding gap (511) is a gap between the two steam sealing rotating shafts (51), one end of the steam sealing expansion plate (52) is fixedly arranged on the side wall of the steam sealing rotating shaft (51), sliding vertical grooves (211) are respectively formed in the tops of the side walls, facing each other, of the semi-sealing steam sealing shell (22) and the steam sealing baffle (23), the sliding vertical grooves (211) are mutually communicated with the feeding cavity (21), the sliding plates (53) are fixedly arranged at one ends of the steam sealing expansion plate (52) far away from the textile fabric (100), the sliding vertical grooves (53) are slidingly arranged in the sliding vertical grooves (211) and are respectively communicated with the top of the steam sealing baffle (23) and the sliding baffle (212) and are respectively formed in the top of the semi-sealing baffle plate (22), the movable clamping rod (54) is fixedly arranged on one side wall, far away from the vapor seal expansion plate (52), of the sliding plate block (53), the movable clamping rod (54) is slidably clamped in the movable clamping groove (212), and the central axis of the vapor seal rotating shaft (51) is higher than that of the movable clamping rod (54).

7. The steam sealing energy-saving device of a steam box according to claim 6, characterized in that a containing groove (213) is formed in the top of the semi-closed steam sealing shell (22) and the top of the steam sealing baffle plate (23), the top of the containing groove (213) is mutually communicated with the movable clamping groove (212), a plurality of longitudinal telescopic springs (55) are fixedly arranged at the bottom of the containing groove (213), the same telescopic baffle plate (56) is fixedly arranged at the top of the plurality of longitudinal telescopic springs (55), and the telescopic baffle plate (56) is slidably arranged in the movable clamping groove (212) and the containing groove (213).

8. The steam sealing energy-saving device of a steam box according to claim 7, characterized in that a plurality of pipe grooves (214), water storage grooves (215), a plurality of drainage grooves (216) and a plurality of linkage vertical grooves (217) are formed in the top of the semi-closed steam sealing shell (22) and the steam sealing baffle plate (23), the shaft ends of the plurality of pipe grooves (214) are mutually communicated with one side of the movable clamping groove (212), one side of the water storage groove (215) is mutually communicated with one side of the bottom of the movable clamping groove (212), the water storage groove (215) is vertically arranged with the movable clamping groove (212), the end parts of the plurality of drainage grooves (216) are mutually communicated with one side of the bottom of the water storage groove (215), a penetrating pipe of the drainage grooves (216) is connected to the outer side wall of the semi-closed steam sealing shell (22) or the steam sealing baffle plate (23), an L-shaped guide plate (24) is fixedly arranged on the outer side wall of the semi-closed steam sealing shell (22) and the steam sealing baffle plate (23), the bottom of the plurality of vertical grooves (217) is mutually communicated with one side of the movable clamping groove (212), the bottom of the movable clamping groove (212) is fixedly arranged on the bottom of the movable clamping groove (218), and the upper portion of the movable clamping groove (218) is fixedly connected with a memory rod (218), and the memory rod (218) is fixedly arranged in a mode.

9. The steam sealing energy-saving device of a steam box according to claim 8, characterized in that a plurality of steam pipes (25) are fixedly arranged on the outer side walls of the semi-closed steam sealing shell (22) and the steam sealing baffle plate (23), the steam pipes (25) are mutually corresponding to the pipe grooves (214), the pipe grooves (214) are mutually communicated with the steam pipes (25), and a water stop plate (251) is convexly arranged at the bottom of one end, close to the pipe grooves (214), of the steam pipes (25).

10. The steam sealing energy-saving device of the steam box according to claim 9, wherein steam sealing convex blocks (512) are convexly arranged on the side wall of the steam sealing rotating shaft (51), and the steam sealing convex blocks (512) of the two steam sealing rotating shafts (51) are symmetrically arranged.