CN204875191U - Energy -conserving liquid stream dyeing machine of ultra -temperature - Google Patents

Energy -conserving liquid stream dyeing machine of ultra -temperature Download PDF

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Publication number
CN204875191U
CN204875191U CN201520473990.0U CN201520473990U CN204875191U CN 204875191 U CN204875191 U CN 204875191U CN 201520473990 U CN201520473990 U CN 201520473990U CN 204875191 U CN204875191 U CN 204875191U
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China
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pipeline
housing
heat exchanger
inner chamber
water
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Expired - Fee Related
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CN201520473990.0U
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Chinese (zh)
Inventor
吴承展
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KYOTO MACHINERY CO Ltd
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KYOTO MACHINERY CO Ltd
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Abstract

The utility model provides an energy -conserving liquid stream dyeing machine of ultra -temperature, includes a barrel, heat exchanger and pump are connected respectively to the both ends of barrel, are equipped with first pipeline in the inner chamber of heat exchanger's first casing, after the inner chamber of carrying the first casing of steam entering, heat the water in the first pipeline, and the second casing are connected to the one end of first casing, is equipped with heating element again in the second casing to the heating is outwards flowed by heat exchanger's export by the fluid of the play water end (W. E. ) outflow of first pipeline again. From this, utilize the pressure effect of pump, can make dye liquor circulation flow between heat exchanger and barrel, and via heat exchanger once or quadratic heating, then can effectively promote heating temperature with output high temperature fluid, to the operation of dyeing of the cloth in the barrel, or let the user comply with need to use different heating methods with elasticity.

Description

Super high-temp. energy-saving liquid-flow dyeing machine
Technical field
The utility model has about a kind of super high-temp. energy-saving liquid-flow dyeing machine, and espespecially one has two independently heating pipe lines.
Background technology
When generally dip-dye operation being carried out to fabric, be different to select the type of dying cloth be suitable for according to the water imbibition of fabric, to reaching required dip-dye quality and obtaining preferably economic benefit.And at present conventional textile dyeing machinery divides into two kinds usually, a kind ofly to weave cotton cloth the cylindrical fabric dyeing machine of matter for being applicable to the strong cotton of water imbibition, another kind of for being applicable to the long tube type textile dyeing machinery of the fine cloth matter of the weak length of water imbibition.Wherein, cylindrical fabric dyeing machine is mainly around on the net wheel of enclosure with a cloth roll, the pressure effect of recycling pump, makes the dye liquor through heat exchanger heats accelerate outwards to spray by the water drain hole of net wheel, carries out dyeing operation to cloth.Long tube type textile dyeing machinery is mainly provided with the cylindrical shell of an elongated tubular, by cylindrical shell splendid attire dye liquor and the runner as fabric circulation, then coordinates by the conveying of band cloth apparatus promotion fabric circulation, enables the whole dipping bath of fabric in dye liquor, carry out dyeing operation to cloth.
Above-mentioned two kinds of textile dyeing machinerys, in the dyeing course of cloth, all according to the characteristic of different cloth, must control the temperature of dye liquor, just can reach best dyeing quality.And when reality uses, the heat exchanger of textile dyeing machinery mainly utilizes steam to carry out heat exchange, the temperature of dye liquor in pipeline is allowed to rise, and heat in this way, the temperature of dye liquor is the highest only can reach about about 140 DEG C, for needing higher temperature just can reach for the cloth of better dyeing quality, above-mentioned heat exchange method cannot meet demand; Moreover the failure risk of single kind of heat exchange method is higher, use also lacks flexibility.
Utility model content
In view of this, in order to provide a kind of structure being different from common technology, and improve above-mentioned shortcoming, creator amasss experience for many years and constantly researches and develops improvement, then has generation of the present utility model.
An object of the present utility model is providing a kind of super high-temp. energy-saving liquid-flow dyeing machine, by arranging a heating pipe line in a housing, and with heating component again and again, the fluid that pipeline flows out is carried out to the structure of heat exchange, the heat exchanger that can solve conventional dyeing machine effectively cannot promote the high problem of the failure risk of temperature and single kind of heat exchange method, and effectively can promote heating-up temperature to increase the Color of cloth and to maintain dyeing quality, according to the needs of user with the different mode of heating of Flexible use, and reduce the risk causing because of single heating mode fault and produce and pause.
For reaching the object of above-mentioned creation, the utility model provides a kind of super high-temp. energy-saving liquid-flow dyeing machine, comprise a cylindrical shell, the two ends of cylindrical shell connect a heat exchanger and a pump respectively, utilize the pressure effect of pumping, make to enter dye liquor in heat exchanger after heat exchanger heats by the water inlet of heat exchanger, flowed out by the outlet of heat exchanger and enter in cylindrical shell, dyeing operation is carried out to the cloth in cylindrical shell; Wherein:
This heat exchanger comprises one first housing, and this water inlet is located on this first housing, for the water of input for heating; The inner chamber of this first housing is provided with at least one first pipeline, and this at least one first pipeline is communicated with this water inlet; This first housing has a steam inlet, enters the inner chamber of this first housing for delivering vapor, to heat the water in this first pipeline;
This at least one first pipeline has a water intake end and a water side, and this water intake end is communicated with this water inlet; And
This heat exchanger more comprises one second housing, this second housing has an inner chamber, one end of this second housing connects one end of this first housing, heating component is again and again provided with in this second housing, with the fluid that the water side of heating this at least one first pipeline is flowed out, and outwards flowed out by the outlet of this heat exchanger.
Described super high-temp. energy-saving liquid-flow dyeing machine, wherein: this outlet is located on this second housing, the water side of this outlet and this at least one first pipeline is interconnected, this again heating component comprise at least one second pipeline, this at least one second pipeline is placed in the inner chamber of this second housing, this at least one second pipeline has a liquid feeding end and a liquid returning end, makes to flow in this at least one second pipeline for conveying fluid.
Described super high-temp. energy-saving liquid-flow dyeing machine, wherein: more comprise a junction, one end of this connecting portion connects this second housing, the other end of this connecting portion is provided with an inlet and a liquid return hole, the inner chamber of this connecting portion has a dividing plate, being provided with this inner chamber to separate is spatial accommodation and once spatial accommodation on, and on this, spatial accommodation is communicated with the liquid feeding end of this inlet and this at least one second pipeline respectively, and this lower spatial accommodation is communicated with the liquid returning end of this liquid return hole and this at least one second pipeline respectively.
Described super high-temp. energy-saving liquid-flow dyeing machine, wherein: this again heating component comprise at least one second pipeline and a heater, this at least one second pipeline is placed in the inner chamber of this second housing, this at least one second pipeline has a water inlet end and a discharge ends, the water side of this water inlet end and this at least one first pipeline is interconnected, this discharge ends and this outlet; And this heater connects this second housing, for this at least one second pipeline of this second housing cavity of heating.
Described super high-temp. energy-saving liquid-flow dyeing machine, wherein: more comprise a junction, this outlet is located on this connecting portion, and the two ends of this connecting portion connect this first housing and this second housing respectively; The inner chamber of this connecting portion has a dividing plate, being provided with this inner chamber to separate is spatial accommodation and once spatial accommodation on, on this, spatial accommodation is communicated with the discharge ends of this outlet and this at least one second pipeline respectively, and this lower spatial accommodation is communicated with the water inlet end of this at least one second pipeline and the water side of this at least one first pipeline respectively.
Therefore, the utility model has following advantage:
1, the utility model heats the fluid for exporting respectively with two different heat exchange methods, therefore, when be applied to textile dyeing machinery cloth dyeing operation on time, effectively can promote heating-up temperature, to meet the user demand of specialty fibers cloth, make the Color of increase cloth and maintain dyeing quality.
2, the utility model can allow user heat the fluid in the first pipeline or in the second housing respectively with two different heat exchange methods simultaneously, a kind of heat exchange method wherein can also be selected to heat, therefore, not only effectively can reduce the risk causing because of single heating mode fault and produce and pause, and quite there is elasticity in use.
For ease of having a better understanding, after being hereby specified in the utility model:
Accompanying drawing explanation
Fig. 1 is the using state schematic diagram of preferred embodiment of the present utility model;
Fig. 2 is the front view of the heat exchanger of preferred embodiment of the present utility model;
Fig. 3 is the a-a ' profile of the 2nd figure;
Fig. 4 is the using state figure of the heat exchanger of preferred embodiment of the present utility model;
Fig. 5 is the front view of another heat exchanger enforcement pattern of preferred embodiment of the present utility model;
Fig. 6 is the b-b ' profile of Fig. 5;
Fig. 7 is the using state figure of another heat exchanger enforcement pattern of preferred embodiment of the present utility model.
Description of reference numerals: super high-temp. energy-saving liquid-flow dyeing machine 1; Cylindrical shell 11; Net wheel 111; Water drain hole 112; Connecting line 113,114; Cloth 115; Pump 12; Heat exchanger 13; Outlet 131; Water inlet 132; First housing 2; Door closure 21; Left location-plate 22; Locating hole 221; Right location-plate 24; Locating hole 241; First pipeline 25; Water side 251; Water intake end 252; Filter screen 26; Steam inlet 27; Heating space 28; Second housing 3,5; Heating component 30,6 again; Location-plate 31,51; Locating hole 311,511; Liquid feeding end 312; Liquid returning end 313; Second pipeline 33,53; Connecting portion 4,7; Inlet 41; Liquid return hole 42; Dividing plate 43,71; Upper spatial accommodation 44,72; Lower spatial accommodation 45,73; Ventilation mouth 52; Heater 54; Water inlet end 512; Discharge ends 513.
Detailed description of the invention
Refer to shown in Fig. 1, it is the preferred embodiment of the utility model super high-temp. energy-saving liquid-flow dyeing machine 1, comprises cylindrical shell 11, pump 12 and a heat exchanger 13.Wherein, cylindrical shell 11 inside is provided with a net wheel 111, net wheel 111 surface is provided with multiple water drain hole 112, the left end of cylindrical shell 11 and lower end are connected with a connecting line (113,114) respectively, one end of one connecting line 113 is connected with net wheel 111, the other end of connecting line 113 connects the outlet 131 of heat exchanger 13, and another connecting line 114 connects pump 12, and pump 12 connects the water inlet 132 of heat exchanger 13.Thus, a cloth 115 is wound on net wheel 111, utilizes the pressurization of pump 12 that the dye liquor heated through over-heat-exchanger 13 can be made outwards to be sprayed by the water drain hole 112 of net wheel 111, cloth 115 is dyeed, remaining dye liquor recycling use after dyeing.During enforcement, this cylindrical shell 11 can be also elongated tubular, by cylindrical shell 11 splendid attire dye liquor and the runner as fabric circulation, then coordinates by the conveying of band cloth apparatus promotion fabric circulation, enables the whole dipping bath of fabric in dye liquor, carry out dyeing operation to cloth.
Refer to shown in Fig. 2, Fig. 3, this heat exchanger 13 comprises one first housing 2,1 second housing 3 and a junction 4.Wherein, cylindrically, one end of the first housing 2 axis is provided with door closure 21 to the first housing 2 outline, and the other end of the first housing 2 axis is provided with left location-plate 22, and left location-plate 22 is provided with multiple locating hole 221, and this water inlet 132 is located on the first housing 2.
The inner chamber of the first housing 2 is provided with a right location-plate 24, multiple first pipeline 25 and filter screen 26, right location-plate 24 is provided with multiple locating hole 241, the left end of multiple first pipeline 25 inserts the locating hole 221 of left location-plate 22 respectively, to form a water side 251, the right-hand member of multiple first pipeline 25 inserts the locating hole 241 of right location-plate 24 respectively, to form a water intake end 252.Separately, the first housing 2 is provided with a steam inlet 27, and form a heating space 28 between left location-plate 22 and right location-plate 24, heating space 28 is communicated with steam inlet 27.And this filter screen 26 is socketed on the outer peripheral edge of right location-plate 24 and multiple first pipeline 25, to filter the water entered by water inlet 132 in multiple first pipeline 25.
Cylindrically, the left end that the right-hand member of the second housing 3 connects left location-plate 22, second housing 3 axis of the first housing 2 is provided with location-plate 31 to this second housing 3 outline, and location-plate 31 is provided with multiple locating hole 311.This outlet 131 is located on the second housing 3, and the water side 251 of outlet 131 and the first pipeline 25 is interconnected.The inner chamber of the second housing 3 is provided with again and again heating component 30, heating component 30 comprises multiple second pipeline 33 again, one end of multiple second pipeline 33 inserts the locating hole 311 of location-plate 31 first half respectively, to form a liquid feeding end 312, the other end of multiple second pipeline 33 inserts the locating hole 311 of location-plate 31 Lower Half respectively, to form a liquid returning end 313.The class of filling up heat kerosene in the pipe of the second pipeline 33 can form the fluid of high temperature.
And the right part of this connecting portion 4 connects the location-plate 31 of the second housing 3 left end, the right-hand member of connecting portion is provided with inlet 41 and a liquid return hole 42, the inner chamber of connecting portion 4 has a dividing plate 43, it is spatial accommodation 44 and once spatial accommodation 45 on that the inner chamber of connecting portion 4 separates by dividing plate 43, upper spatial accommodation 44 is communicated with the liquid feeding end 312 of inlet 41 and the second pipeline 33 respectively, and lower spatial accommodation 45 is communicated with the liquid returning end 313 of liquid return hole 42 and the second pipeline 33 respectively.
Thus, as shown in Figure 4, after the water for heating enters in multiple first pipeline 25 by water inlet 132, through carrying out heat exchange action with the steam in the heating space 28 of the first housing 2, water temperature in first pipeline 25 can be promoted to the highest temperature to about about 140 DEG C, and when the steam of high temperature passes through the inner chamber of the second housing 3, via the heat exchange of the high temperature heat kerosene in the second pipeline 33, then steam temperature can be promoted to more than about 200 DEG C again, and outwards be exported by the outlet 131 of the second housing 3.During enforcement, when the steam temperature exported is too high, the water of low temperature can also be inputted via steam inlet 27, to reduce the steam temperature in the first pipeline 25, to reach the output requirement required for user.
Refer to shown in Fig. 5, Fig. 6, it is the enforcement pattern of another heat exchanger of the present utility model, and itself and above-mentioned heat exchanger difference are: one end of the second housing 5 axis is provided with location-plate 51, and location-plate 51 is provided with multiple locating hole 511.Second housing 5 is provided with a ventilation mouth 52.This again heating component 6 comprise multiple second pipeline 53 and heater 54, one end of multiple second pipeline 53 inserts the locating hole 511 of location-plate 51 Lower Half respectively, to form a water inlet end 512, the other end of multiple second pipeline 53 inserts the locating hole 511 of location-plate 51 first half respectively, to form a discharge ends 513.And this heater 4 is gas combustion machine, the heating gate of heater 4 is towards the bending place of U-shaped second pipeline 33, and to heat multiple second pipeline 33, the waste gas after burning is discharged by ventilation mouth 32.
This connecting portion 7 is outline three-way pipe in T shape, and this outlet 131 is positioned at an end of connecting portion 7, and other two opposite ends of connecting portion 7 connect the left location-plate 22 of the first housing 2 and the location-plate 51 of the second housing 5 respectively.The inner chamber of connecting portion 7 has an arc-shaped partition 71, it is spatial accommodation 72 and once spatial accommodation 73 on that the inner chamber of connecting portion 7 separates by arc-shaped partition 71, upper spatial accommodation 72 is communicated with the discharge ends 513 of outlet 131 and multiple second pipeline 53 respectively, and lower spatial accommodation 73 is communicated with the water inlet end 512 of multiple second pipeline 53 and the water side 251 of multiple first pipeline 25 respectively.
Thus, as shown in Figure 7, when the steam of high temperature is by multiple second pipeline 53, via heating again of heater 54, then steam temperature can be promoted to more than about 200 DEG C again, and be outwards exported by the outlet 131 of connecting portion 7.
Therefore, the utility model has following advantage:
1, the utility model heats the fluid for exporting respectively with two different heat exchange methods, therefore, when be applied to textile dyeing machinery cloth dyeing operation on time, effectively can promote heating-up temperature, to meet the user demand of specialty fibers cloth, make the Color of increase cloth and maintain dyeing quality.
2, the utility model can allow user heat the fluid in the first pipeline or in the second housing respectively with two different heat exchange methods simultaneously, a kind of heat exchange method wherein can also be selected to heat, therefore, not only effectively can reduce the risk causing because of single heating mode fault and produce and pause, and quite there is elasticity in use.
In sum, according to content disclosed above, the utility model really can reach the object of expection, there is provided a kind of heating-up temperature that can not only promote to meet user demand, the risk causing because of single heating mode fault and produce and pause can be reduced, and flexible super high-temp. energy-saving liquid-flow dyeing machine can be had in use, have the value that industry utilizes, therefore propose utility application in accordance with the law.

Claims (5)

1. a super high-temp. energy-saving liquid-flow dyeing machine, comprise a cylindrical shell, the two ends of cylindrical shell connect a heat exchanger and a pump respectively, pump is utilized to make to enter dye liquor in heat exchanger after heat exchanger heats by the water inlet of heat exchanger, flowed out by the outlet of heat exchanger and enter in cylindrical shell, dyeing operation is carried out to the cloth in cylindrical shell; It is characterized in that:
This heat exchanger comprises one first housing, and this water inlet is located on this first housing, for the water of input for heating; The inner chamber of this first housing is provided with at least one first pipeline, and this at least one first pipeline is communicated with this water inlet; This first housing has a steam inlet, enters the inner chamber of this first housing for delivering vapor, to heat the water in this first pipeline;
This at least one first pipeline has a water intake end and a water side, and this water intake end is communicated with this water inlet; And
This heat exchanger more comprises one second housing, this second housing has an inner chamber, one end of this second housing connects one end of this first housing, heating component is again and again provided with in this second housing, with the fluid that the water side of heating this at least one first pipeline is flowed out, and outwards flowed out by the outlet of this heat exchanger.
2. super high-temp. energy-saving liquid-flow dyeing machine as claimed in claim 1, it is characterized in that: this outlet is located on this second housing, the water side of this outlet and this at least one first pipeline is interconnected, this again heating component comprise at least one second pipeline, this at least one second pipeline is placed in the inner chamber of this second housing, this at least one second pipeline has a liquid feeding end and a liquid returning end, makes to flow in this at least one second pipeline for conveying fluid.
3. super high-temp. energy-saving liquid-flow dyeing machine as claimed in claim 2, it is characterized in that: more comprise a junction, one end of this connecting portion connects this second housing, the other end of this connecting portion is provided with an inlet and a liquid return hole, the inner chamber of this connecting portion has a dividing plate, being provided with this inner chamber to separate is spatial accommodation and once spatial accommodation on, on this, spatial accommodation is communicated with the liquid feeding end of this inlet and this at least one second pipeline respectively, and this lower spatial accommodation is communicated with the liquid returning end of this liquid return hole and this at least one second pipeline respectively.
4. super high-temp. energy-saving liquid-flow dyeing machine as claimed in claim 1, it is characterized in that: this again heating component comprise at least one second pipeline and a heater, this at least one second pipeline is placed in the inner chamber of this second housing, this at least one second pipeline has a water inlet end and a discharge ends, the water side of this water inlet end and this at least one first pipeline is interconnected, this discharge ends and this outlet; And this heater connects this second housing, for this at least one second pipeline of this second housing cavity of heating.
5. super high-temp. energy-saving liquid-flow dyeing machine as claimed in claim 4, it is characterized in that: more comprise a junction, this outlet is located on this connecting portion, and the two ends of this connecting portion connect this first housing and this second housing respectively; The inner chamber of this connecting portion has a dividing plate, being provided with this inner chamber to separate is spatial accommodation and once spatial accommodation on, on this, spatial accommodation is communicated with the discharge ends of this outlet and this at least one second pipeline respectively, and this lower spatial accommodation is communicated with the water inlet end of this at least one second pipeline and the water side of this at least one first pipeline respectively.
CN201520473990.0U 2015-07-03 2015-07-03 Energy -conserving liquid stream dyeing machine of ultra -temperature Expired - Fee Related CN204875191U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114016231A (en) * 2021-11-26 2022-02-08 宜昌市欣龙卫生材料有限公司 Dyeing system and dyeing method

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114016231A (en) * 2021-11-26 2022-02-08 宜昌市欣龙卫生材料有限公司 Dyeing system and dyeing method

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GR01 Patent grant
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20151216

Termination date: 20190703

CF01 Termination of patent right due to non-payment of annual fee