CN114635248A

CN114635248A - Steam humidifying device for textile shaping

Info

Publication number: CN114635248A
Application number: CN202210303447.0A
Authority: CN
Inventors: 韦庆学
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-03-24
Filing date: 2022-03-24
Publication date: 2022-06-17

Abstract

The invention discloses a steam humidifying device for textile shaping, which belongs to the field of textile shaping, and is characterized in that a thermal circulation collector is additionally arranged on the basis of a steam box in the prior art, the steam is condensed on a conical condenser by utilizing the upward-moving characteristic of the steam, condensed liquid drops slide into an umbrella-shaped collecting tray along the outer surfaces of the conical condenser and a reflux column to realize recovery, the liquid drops are prevented from dropping on the textile to form stains, a water guide member absorbs water from the liquid and upwards transmits the water to a water absorber to realize the separation of organic substances, so that the post-treatment is convenient, the heat is absorbed from the steam while the condensation is recovered, thermal expansion balls expand to extrude easy-to-detach water absorption balls, the easy-to-detach water absorption balls are desorbed to keep sufficient water absorption, and the desorbed water flows to the outer surface of the conical condenser through a reflux channel to promote the recovery of condensed liquid drops, thereby further improving the purge gas effect.

Description

Steam humidifying device for textile shaping

Technical Field

The invention relates to the field of textile sizing, in particular to a steam humidifying device for textile sizing.

Background

Textile, i.e. a product made by textile processing. Including yarns, wovens, knits, braids, and the like. It is divided into woven fabric and knitted fabric. China is a large country for textile production and export, the Chinese textile industry develops for many years, has obvious competitive advantages, has the most complete industrial chain in the world and the highest processing matching level, continuously enhances the self-regulation capacity of a plurality of developed industrial clusters for coping with market risks, and provides a solid guarantee for keeping the steady development pace of the industry.

During the textile finishing process, the fabric is subjected to a variety of complex actions (including physical mechanical, chemical). The product has changed external form and structure size, and some products even lose the form, appearance and style of the fabric, thus seriously affecting the wearability. Ensuring the stability of the external form and dimensions of the fabric is therefore an important criterion for balancing the quality stars. The treatment process for stabilizing the appearance, shape and size of the fabric is generally called setting treatment, and for the characteristics of different fiber fabrics, there are many different setting treatment methods, including chemical methods (such as resin finishing of cotton fabric, mercerization, etc.) and physical and mechanical methods (such as wool fabric boiling, decating, synthetic fiber heat setting, etc.).

At present, the fabric is treated by superheated steam mainly in heat setting under normal pressure, and the temperature can reach about 130 ℃. The method can shorten heat treatment time, improve production efficiency, improve color brightness, prevent fiber yellowing, and improve fabric hand feeling, style and elasticity. However, in actual production, organic substances such as dyes, auxiliaries and coatings on textiles can be released to cause air pollution, and the existing steam box is not provided with a good gas treatment device.

Disclosure of Invention

1. Technical problem to be solved

In view of the problems in the prior art, an object of the present invention is to provide a steam humidifying device for textile sizing, which has the advantages of recycling condensed organic gas to purify the gas, recovering the steam containing organic substances by condensation, and absorbing the heat of the steam, so that the improved steam box can repeatedly absorb the condensed water, on one hand, the steam humidifying device is used for separating the organic substances to facilitate the treatment, and on the other hand, the steam humidifying device is used for further promoting the condensation, thereby improving the purification effect.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A steam humidifying device for shaping textiles is characterized in that a thermal cycle collector is additionally arranged on the basis of a steam box in the prior art, the thermal cycle collector comprises a conical condenser, the lower end of the conical condenser is communicated with a reflux column, the lower end of the reflux column is connected with an umbrella-shaped collecting tray, the inner wall of the upper end of the conical condenser is provided with a desorption cavity, a water absorber is arranged in the desorption cavity, a plurality of heat absorption wires arranged around the desorption cavity are embedded in the inner wall of the conical condenser, a heat-conducting soft wire is fixedly connected between the heat-absorbing wire and the water absorber, a water guide piece is arranged in the reflux column, the upper end of the water guide piece penetrates into the desorption cavity and is connected with the water absorber, the inner wall of the lower end of the conical condenser is provided with a plurality of return channels communicated with the desorption cavity, the lower end of the return column is fixedly connected with a plurality of water absorbing strips, and the water absorbing strips penetrate through the side wall of the return column and extend into the umbrella-shaped collecting tray; when organic matter evaporates with the steam, the existing steam box has the advantage of recycling condensed organic gas to realize gas purification.

Furthermore, the outer surfaces of the conical condensers and the outer surfaces of the reflux columns are subjected to smoothing treatment, so that the surface resistance is reduced, liquid at a condensation position can better slide down, the two adjacent conical condensers are connected, and when steam carrying organic substances rises to the conical condensers, the steam is condensed into liquid drops in the conical condensers due to the reduction of temperature.

Furthermore, a plurality of guiding gutters are arranged on the outer surface of the conical condenser, so that liquid can slide down along the surface of the conical condenser and cannot directly drop back to the textile, and the outlets of the return channels are vertically distributed along the guiding gutters.

Furthermore, the water absorber comprises an easily-detached water absorption ball, a thermal expansion ball fixedly connected with the heat conduction soft wire is embedded in the easily-detached water absorption ball, and the heat absorption wire absorbs heat of steam and then transmits the heat to the thermal expansion ball through the heat conduction soft wire, so that the thermal expansion ball expands to extrude the easily-detached water absorption ball, and the easily-detached water absorption ball which absorbs full water can be dehydrated.

Furthermore, the inner wall of the desorption cavity is fixedly connected with two extrusion assisting plates matched with the easy-desorption water absorption balls, so that the easy-desorption water absorption balls can be desorbed better by matching with the expansion of the thermal expansion balls, and the extrusion assisting plates are hollow nets so as not to obstruct the desorption of water.

Further, the water guide piece comprises a plurality of transfer balls and water guide belts, the transfer balls and the water guide belts are arranged at intervals, and the transfer balls and the water guide belts realize upward transfer of water so as to absorb water from the organic substances condensed back into liquid.

Furthermore, the water absorption of the transfer balls is larger than that of the water guide belt, the water absorption of the transfer balls is sequentially increased from bottom to top, the upward water transfer resistance is larger due to the action of gravity, and the water absorption of the transfer balls is larger upwards to overcome the action of gravity in order to enable water to be smoothly transferred upwards.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) this scheme is through on prior art steam chest's basis through addding the thermal cycle collector, the characteristic that utilizes steam to go up makes its condensation on the conical condenser, the liquid drop after the condensation is in order to realize retrieving in the outer surface landing of conical condenser and backward flow post to umbrella-type catch tray, prevent that the liquid drop from dripping to the fabrics and form the stain, water guide absorbs water and upwards transmits for the water absorber from liquid after retrieving, in order to realize organic substance's separation, thereby make things convenient for the post processing, absorb the heat from the steam when the condensation is retrieved, the heat makes the thermal expansion ball inflation easily detach the ball that absorbs water with the extrusion, thereby let easily detach the ball that absorbs water desorption in order to keep sufficient hydroscopicity, the water that breaks away from flows the outer surface of conical condenser by the backward flow way and in order to promote the recovery of condensation liquid drop, thereby further improve the gas purification effect.

(2) The outer surfaces of the conical condensers and the outer surfaces of the reflux columns are subjected to smoothing treatment, so that the surface resistance is reduced, liquid at a condensation position can better slide down, the two adjacent conical condensers are connected, and when steam carrying organic substances rises to the conical condensers, the steam is condensed into liquid drops in the conical condensers due to the reduction of temperature.

(3) A plurality of guiding gutters are arranged on the outer surface of the conical condenser, so that liquid can slide down along the surface of the conical condenser without directly dripping back to textiles, and outlets of the return channel are vertically distributed along the guiding gutters.

(4) The water absorber comprises an easily-detached water absorption ball, a thermal expansion ball fixedly connected with a heat conduction soft wire is embedded in the easily-detached water absorption ball, the heat absorption wire absorbs heat of steam and then transmits the heat to the thermal expansion ball through the heat conduction soft wire, so that the thermal expansion ball expands to extrude the easily-detached water absorption ball, and the easily-detached water absorption ball which absorbs full water can be dehydrated.

(5) The inner wall of the desorption cavity is fixedly connected with two extrusion assisting plates matched with the water absorption balls easy to desorb, so that the water absorption balls easy to desorb are better desorbed by matching with the expansion of the thermal expansion balls, and the extrusion assisting plates are hollow nets so as not to obstruct the desorption of water.

(6) The water guide piece comprises a plurality of transfer balls and water guide belts, the transfer balls and the water guide belts are arranged at intervals, and the transfer balls and the water guide belts realize upward transfer of water so as to absorb water from organic substances condensed back into liquid.

(7) The water absorption of the transfer balls is larger than that of the water guide belt, the water absorption of the transfer balls is sequentially increased from bottom to top, the upward transfer resistance of water is larger under the action of gravity, and the water absorption of the transfer balls is larger upwards to overcome the action of gravity in order to enable water to be smoothly transferred upwards.

Drawings

FIG. 1 is a front view of the apparatus of the present invention;

FIG. 2 is a diagram of the initial condensation state of the vapor in accordance with the present invention;

FIG. 3 is a diagram illustrating a condensed liquid droplet recovery state according to the present invention;

FIG. 4 is a cross-sectional view of a thermal cycle collector of the present invention;

FIG. 5 is a perspective view of the conical condenser of the present invention;

FIG. 6 is a perspective view of an umbrella shaped collection tray of the present invention;

FIG. 7 is a cross-sectional view of an umbrella shaped collection tray of the present invention;

FIG. 8 is a cross-sectional view of the water aspirator of the present invention;

FIG. 9 is a view of the structure at A in FIG. 4;

fig. 10 is a front view of the water deflector of the present invention.

The reference numbers in the figures illustrate:

1 gas collection box, 201 conical condenser, 2011 diversion trench, 202 reflux column, 2021 magnetic column, 203 umbrella-shaped collection tray, 2031 condensation prevention cover, 3 desorption cavity, 4 water absorber, 401 easy desorption water absorption ball, 402 thermal expansion ball, 403 extrusion boosting board, 5 heat absorption wire, 501 heat conduction soft wire, 6 reflux channel, 601 deceleration strip, 7 water guide piece, 701 transfer ball, 702 water guide strip, 8 water absorption strip.

Detailed Description

In this embodiment 1, the technical solution will be clearly and completely described in conjunction with the disclosed drawings, so that the purpose, technical solution and beneficial effects of the embodiments of the present disclosure will be more clear. It is to be understood that the described embodiments are only a few embodiments of the present disclosure, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the described embodiments of the disclosure without any inventive step, are within the scope of protection of the disclosure.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by those of skill in the art to which this disclosure belongs. The use of "first," "second," and similar terms in this disclosure is not intended to indicate any order, quantity, or importance, but rather is used to distinguish one element from another. The word "comprising" and similar words are intended to mean that the elements or items listed before the word cover the elements or items listed after the word and their equivalents, without excluding other elements or items. "upper", "lower", "inside", "outside", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

Example (b):

referring to fig. 1-4, the inner wall of the upper end of the gas collecting box 1 is fixedly connected with a plurality of thermal cycle collectors which are arranged at equal intervals, each thermal cycle collector comprises a conical condenser 201, the lower end of each conical condenser 201 is communicated with a reflux column 202, the lower end of each reflux column 202 is connected with an umbrella-shaped collecting tray 203, the outer surfaces of the conical condensers 201 and the reflux columns 202 are both subjected to smoothing treatment, so as to reduce surface resistance and enable liquid at a condensation position to better slide down, and the two adjacent conical condensers 201 are connected with each other, when steam carrying organic substances rises onto the conical condensers 201, the steam is condensed into liquid drops in the conical condensers 201 due to temperature reduction, the outer surface of the conical condensers 201 is provided with a plurality of flow guide grooves 2011, so as to enable the liquid to slide down along the surface of the conical condensers 201 and not to directly drop back onto textiles, and the outlets of the return passages 6 are vertically distributed along the guide grooves 2011;

referring to fig. 5-7, when the vapor with organic substances rises to the conical condenser 201, the organic substances are condensed into droplets in the conical condenser 201 due to the difference between the upper and lower temperatures and the heat dissipation, and the droplets slide down to the reflux column 202 along the flow guide groove 2011 and then slide down to the umbrella-shaped collection tray 203 from the reflux column 202, so as to be collected;

referring to fig. 8 and 10, the water guide 7 includes a plurality of transfer balls 701 and a water guide belt 702, the transfer balls 701 and the water guide belt 702 are arranged at intervals, the transfer balls 701 and the water guide belt 702 realize upward transfer of water, so that water is absorbed from organic substances condensed back into liquid, the water absorption of the transfer balls 701 is greater than that of the water guide belt 702, the water absorption of the transfer balls 701 is sequentially increased from bottom to top, the resistance of the upward transfer of water is greater due to the action of gravity, and in order to enable smooth upward transfer of water, the water absorption of the transfer balls 701 is larger upwards to overcome the action of gravity, the water absorption strips 8 absorb water from the condensed liquid and transfer the water to the transfer balls 701 and the water guide belt 702, and the transfer balls 701 and the water guide belt 702 finally transfer the water to the easy-to-remove water absorption balls 401;

referring to fig. 4 and 8, the water absorber 4 includes an easy-to-detach water absorption ball 401, a thermal expansion ball 402 fixedly connected with a heat conductive soft wire 501 is embedded in the easy-to-detach water absorption ball 401, and the heat of the steam absorbed by the heat absorption wire 5 is transmitted to the thermal expansion ball 402 through the heat conductive soft wire 501, so that the thermal expansion ball 402 expands to squeeze the easy-to-detach water absorption ball 401, and the easy-to-detach water absorption ball 401 having fully absorbed water can be dehydrated;

referring to fig. 4 and 9, water desorbed from the easy-desorption water absorption ball 401 flows back to the surface of the conical condenser 201 along the return channel 6, each outlet end of the return channel 6 is fixedly connected with a deceleration strip 601, the surface of the deceleration strip 601 has a fluff structure, and the deceleration strip 601 allows the refluxed water to continue to form droplets to promote the recovery of the condensed droplets, thereby further improving the gas purification effect.

The foregoing is only a preferred embodiment of the present invention; the scope of the invention is not limited thereto. Any person skilled in the art should be able to cover the technical scope of the present invention by equivalent or modified solutions and modifications within the technical scope of the present invention.

Claims

1. The utility model provides a steam humidification device for fabrics is stereotyped, includes the steam chest body, gas collection box (1), its characterized in that are installed to the upper end inner wall of steam chest: the upper end inner wall fixedly connected with of gas collection box (1) reads the thermal cycle collector of a equidistant setting, the thermal cycle collector includes toper condenser (201), the lower extreme intercommunication of toper condenser (201) has reflux column (202), and the lower extreme of reflux column (202) is connected with umbrella-type catch tray (203), desorption chamber (3) have been seted up to the upper end inner wall of toper condenser (201), and has placed water absorber (4) in desorption chamber (3), the inner wall of toper condenser (201) is inlayed and is had a plurality of heat absorption silk (5) of surrounding desorption chamber (3) setting, and fixedly connected with heat conduction soft silk (501) between heat absorption silk (5) and water absorber (4), place water guide (7) in reflux column (202), and the upper end of water guide (7) runs through to desorption chamber (3) in and be connected with water absorber (4), the lower extreme inner wall of toper condenser (201) is seted up a plurality of reflux ways that communicate with desorption chamber (3), (4) 6) The lower end of the reflux column (202) is fixedly connected with a plurality of water absorbing strips (8), and the water absorbing strips (8) penetrate through the side wall of the reflux column (202) and extend into the umbrella-shaped collecting tray (203).

2. A steam humidifying device for textile sizing as claimed in claim 1, wherein: the outer surfaces of the conical condensers (201) and the outer surfaces of the reflux columns (202) are subjected to smoothing treatment, and two adjacent conical condensers (201) are connected.

3. A steam humidifying device for textile sizing as claimed in claim 1, wherein: a plurality of guiding gutters (2011) have been seted up to the surface of toper condenser (201), and guiding gutter (2011) vertical distribution is followed to the export of return flow way (6).

4. A steam humidifying device for textile sizing as claimed in claim 1, wherein: the water absorber (4) comprises an easy-to-detach water absorbing ball (401), and a thermal expansion ball (402) fixedly connected with a heat conducting soft wire (501) is embedded in the easy-to-detach water absorbing ball (401).

5. A steam humidifying device for textile sizing as claimed in claim 4, wherein: the inner wall of the desorption cavity (3) is fixedly connected with two extrusion assisting plates (403) matched with the easy desorption water absorption balls (401), and the extrusion assisting plates (403) are hollow nets.

6. A steam humidification device for textile sizing as claimed in claim 1 wherein: every exit end of backward flow way (6) is equal fixedly connected with speed reduction strip (601), and the surface of speed reduction strip (601) has the villus structure.

7. A steam humidifying device for textile sizing as claimed in claim 1, wherein: the lower end of the reflux column (202) is fixedly connected with a magnetic column (2021), and the bottom of the umbrella-shaped collecting tray (203) is provided with a magnetic slot matched with the magnetic column (2021).

8. A steam humidifying device for textile sizing as claimed in claim 1, wherein: the outside parcel of umbrella-type collecting tray (203) has anti-condensation cover (2031), and anti-condensation cover (2031) adopts smooth adiabatic material.

9. A steam humidifying device for textile sizing as claimed in claim 1, wherein: the water guide member (7) comprises a plurality of transmission balls (701) and a water guide belt (702), and the transmission balls (701) and the water guide belt (702) are arranged at intervals.

10. A steam humidifying device for textile sizing as claimed in claim 9, wherein: the water absorption of the transfer balls (701) is larger than that of the water guide belt (702), and the water absorption of the transfer balls (701) is increased from bottom to top in sequence.