CN210826788U - Textile cleaning system - Google Patents

Abstract

The embodiment of the application provides a clean system of fabrics has: the washing machine comprises a washing bin, a first dewatering bin, a rinsing bin and a second dewatering bin, wherein a conveying mechanism is arranged between a textile feeding hole of the first dewatering bin and a textile discharging hole of the washing bin, a conveying mechanism is arranged between a textile discharging hole of the first dewatering bin and a textile feeding hole of the rinsing bin, and a conveying mechanism is arranged between a textile discharging hole of the rinsing bin and a textile feeding hole of the second dewatering bin. The first dewatering bin is arranged between the washing bin and the rinsing bin, and dewatering is carried out between washing and rinsing, so that the textile entering the rinsing bin only carries a small amount of sewage, and the mode of rinsing and cleaning has the advantages of small water consumption and high cleaning degree.

Description

Textile cleaning system

Technical Field

The application relates to the field of textile cleaning, in particular to a textile cleaning system.

Background

The textile is easy to adsorb dirt, so that the production of the textile cleaning industry is promoted, in order to improve the cleaning efficiency, a tunnel type batch processing washing dragon is produced at the present stage, the washing dragon is provided with a plurality of bin bodies, the principle is that each bin body is used as a station link, and therefore the objects to be washed are cleaned in a running water station mode, wherein the objects to be washed can be cleaned in several links such as washing, rinsing, dewatering and the like.

SUMMERY OF THE UTILITY MODEL

The embodiments of the present description provide a textile cleaning system. The cleaning agent is used for solving the problems of large water consumption and low cleaning degree in the cleaning process of the textile in the prior art.

Embodiments of the present description provide a textile cleaning system having:

the washing bin, the first dewatering bin, the rinsing bin and the second dewatering bin;

the washing bin is provided with a textile feeding hole;

the first dewatering bin is provided with a textile feeding hole and a textile discharging hole;

a conveying mechanism is arranged between the textile feeding hole of the first dewatering bin and the textile discharging hole of the washing bin;

a conveying mechanism is arranged between the textile discharge port of the first dewatering bin and the textile feed port of the rinsing bin;

and a conveying mechanism is arranged between the textile discharge port of the rinsing bin and the textile feed port of the second dewatering bin.

Optionally, the washing bin is a multi-stage series washing bin, and has: a detergent washing bin and an aeration washing bin;

the aeration washing bin is provided with an inner bin body, an outer bin body and an aeration mechanism;

the inner chamber body of the aeration washing chamber is provided with: the inner side and the outer side of the inner bin body of the aeration washing bin are communicated through the through holes;

the aeration mechanism is fixed at the bottom of the outer bin body of the aeration washing bin;

the aeration mechanism is provided with an air outlet;

the air outlet of the aeration mechanism faces the inner bin body of the aeration washing bin;

the detergent washing bin is communicated with the aeration washing bin to form the multistage serial washing bin.

Optionally, the microwave oven is characterized by further comprising a microwave oscillator;

the microwave oscillator is fixed at the bottom of the outer bin body of the aeration washing bin.

Optionally, the multi-stage tandem washing bin further has a pretreatment washing bin having a water inlet;

the pretreatment washing bin, the detergent washing bin and the aeration washing bin are communicated to form a multi-stage serial washing bin for textile treatment.

Optionally, each bin body of the multistage series washing bins is provided with an inner bin body, and the rotation axes of the inner bin bodies are parallel;

in the washing bins of the multistage series washing bins, a conveying mechanism is arranged between every two adjacent washing bins.

Optionally, the aeration mechanism has an air suction pump and an aeration disc;

the aeration disc is provided with an air inlet and an air outlet, and the air outlet of the aeration disc forms an air outlet of the aeration mechanism;

and the air outlet of the air pump is communicated with the air inlet of the aeration disc.

Optionally, the air pump has an ozone inlet and an air inlet, the ozone inlet having a valve thereon;

and an air inlet of the air pump is communicated with the top of the outer bin body of the aeration washing bin through a pipeline.

Optionally, the washing bin is a detergent washing bin having a water inlet and a detergent inlet.

Optionally, the detergent washing bin is also provided with a water inlet pipe and a detergent pipe;

the water inlet pipe is communicated with the detergent washing bin, and a water inlet is formed in the wall of the detergent washing bin;

the decontaminating agent pipe is communicated with the water inlet pipe, and a decontaminating agent inlet is formed in the pipe wall of the water inlet pipe.

Optionally, the first dewatering bin is a press type dewatering bin, or the first dewatering bin is a rotary dewatering bin.

According to the various textile cleaning systems described in the specification, the first dewatering bin is arranged between the washing bin and the rinsing bin, and dewatering is carried out between washing and rinsing, so that the textiles entering the rinsing bin only carry a small amount of sewage, and the rinsing and cleaning are carried out in such a way that the water consumption is small and the cleaning degree is high.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

FIG. 1 is a side view of a textile cleaning system according to one embodiment;

FIG. 2 is a top view of a textile cleaning system according to one embodiment;

FIG. 3 is a schematic structural view of an aeration washing chamber according to the fourth embodiment;

FIG. 4 is a schematic structural view of an aeration washing chamber according to the fifth embodiment;

fig. 5 is a schematic diagram of a method for cleaning textiles according to an embodiment of the present disclosure.

Detailed Description

The existing textile cleaning mode is mostly characterized in that one or more washing bins are arranged, water and washing liquid are injected into the washing bins for washing, the washed textile is conveyed to a rinsing bin for rinsing, and the rinsed textile is conveyed to a dewatering bin for dewatering, so that the textile is dried as soon as possible.

The applicant finds that during the drying process of the textile, a small amount of sewage is carried in the textile, and solutes in the sewage remain on the textile after water is evaporated, so that the essence of rinsing is to dilute the liquid carried by the textile, so that only a small amount of dirt remains after the water finally carried in the rinsing object is evaporated during drying or airing, and therefore, the water injection amount and the rinsing frequency often influence the final cleaning effect. The existing cleaning mode is characterized in that a rinsing bin is directly arranged behind a washing bin, so that the concentration of washing liquid and dirt in textiles is higher, and the textiles are directly rinsed, and under the condition of small water injection amount, the dilution effect is poor, and the waste is caused by large water injection amount, so that the problem of large water consumption or low cleanliness is solved.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

In order to make the technical solution of the present invention better understood, the technical solution in the embodiments of the present invention is clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by a person skilled in the art based on the embodiments of the present invention without any creative work shall fall within the protection scope of the embodiments.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances for purposes of describing the embodiments of the invention herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The first embodiment is as follows:

the embodiment of the application provides a clean system of fabrics through set up first dehydration storehouse between washing storehouse and rinsing storehouse, dewaters between washing and rinsing, makes the fabrics that gets into the rinsing storehouse only carry a small amount of sewage, and this kind of mode can reduce the rinsing number of times or reduce the water injection volume of single rinsing, more environmental protection.

Fig. 1 is a side view and fig. 2 is a top view of a textile cleaning system according to an embodiment.

With reference to fig. 1 and 2, the system has a washing compartment 101, a first dewatering compartment 102, a rinsing compartment 103 and a second dewatering compartment 104;

wherein the washing chamber 101 has a textile feed inlet, and f represents the direction of the textile transport;

the first dewatering bin 102 is provided with a textile feeding hole and a textile discharging hole;

a conveying mechanism is arranged between the textile feeding hole of the first dewatering bin 102 and the textile discharging hole of the washing bin;

a conveying mechanism is arranged between the textile discharge port of the first dewatering bin 102 and the textile feed port of the rinsing bin 103;

a conveying mechanism is arranged between the textile discharge port of the rinsing bin 103 and the textile feed port of the second dewatering bin 104.

The first dewatering bin 102 can be a squeezing type dewatering bin, and the textile is squeezed to reduce the clearance of the textile so that sewage carried by the textile is separated from the textile; the first dewatering bin can also be a rotary dewatering bin, when the first dewatering bin rotates, the sewage is separated from the textile by utilizing the inertia of the sewage and the liquidity of the liquid, and the sewage in the textile is removed as much as possible, so that the energy is saved as much as possible in the process of quick drying.

The second dewatering bin 104 may be a press type dewatering bin, a rotating dewatering bin or a drying type dewatering bin, or a plurality of second dewatering bins, for example, the second dewatering bin may be composed of a press type dewatering bin and a drying type dewatering bin, which are not specifically described herein.

Through set up first dehydration storehouse between washing storehouse and rinsing storehouse, dewater between main washing and rinsing, make the fabrics that gets into the rinsing storehouse only carry a small amount of sewage, this kind of mode can reduce the rinsing number of times or reduce the water injection volume of single rinsing, more environmental protection.

Fig. 1 also shows that the system performs spin drying and drying-drying after the rinsing chamber 103, and the drying-drying is performed by the drying-drying chamber 107.

Figure 1 also shows that there is a transfer mechanism between the bins of the system.

The conveying mechanism between the first dewatering bin 102 and the rinsing bin 103 is a first cross conveying mechanism 105, and a second cross conveying mechanism 106 is arranged between the second dewatering bin 104 and the drying dewatering bin 107.

The conveying mechanism can take out the textile from the discharge port of the bin body of the previous link and convey the textile to the feed port of the bin body of the next link when the bin door is opened, the feed port of one link can be provided with a plurality of feed ports, and at the moment, the conveying mechanism can be provided with a transverse conveyor belt for conveying the textile to a specific feed port so as to realize batch processing, which is not specifically explained herein.

Example two:

the washing chamber 101 in the first embodiment can have various forms, which can be embodied in the following two aspects:

in a first aspect, the washing silo 101 may be a washing silo for different washing processes.

The second washing chamber 101 may be a single washing chamber, or may be a multi-stage washing chamber formed by connecting a plurality of washing chambers in series, and the washing processes of the washing chambers in the multi-stage washing chamber may be the same or different.

For the first aspect, there are the following washing processes:

pre-treating and washing, namely injecting water into a washing bin to take away dirt and dust;

washing by using a detergent, namely injecting water and the detergent into a washing bin to generate foam;

aerating and washing, namely injecting compressed gas into the washing bin from the bottom of the washing bin to generate bubbles below the liquid level, wherein the bubbles float to the liquid level to take away dirt and impurities and form foams on the liquid level;

ozone washing, wherein compressed gas containing ozone is injected during aeration washing;

and (3) microwave washing, namely applying microwaves to the washing bin to enable the textiles, the air bubbles and the foams in the washing bin to vibrate.

Corresponding to the washing process of the first aspect, the second embodiment proposes a specific form of the washing chamber 101:

a pretreatment washing bin, an aeration washing bin, an ozone washing bin and a microwave washing bin.

Of course, the washing chamber 101 may be a washing chamber having three washing processes of detergent washing, ozone aeration washing, and microwave washing.

Therefore, the multistage tandem washing chamber may have two or more of a pretreatment washing chamber, an aeration washing chamber, an ozone washing chamber, and a microwave washing chamber.

In one embodiment of example 1, the washing chamber 101 is a multi-stage series washing chamber, and has: a detergent washing bin and an aeration washing bin. The specific structure of each washing chamber will be explained in the following embodiments.

Example three:

the various washing chambers in the second embodiment can have water inlets or detergent inlets, and therefore, the third embodiment illustrates the way of injecting water or detergent into the various washing chambers.

For the pre-treatment silo there may be a water inlet.

The detergent washing bin, the aeration washing bin, the ozone washing bin and the microwave washing bin can be discussed by using the detergent washing bin with a water inlet and a detergent inlet.

Further, on the basis, the detergent washing bin can also be provided with a water inlet pipe and a detergent pipe;

the water inlet pipe is communicated with the detergent washing bin, and a water inlet is formed in the wall of the detergent washing bin;

the decontaminating agent pipe is communicated with the water inlet pipe, and a decontaminating agent inlet is formed on the pipe wall of the water inlet pipe.

Further, in order that the water pressure in the water inlet pipe may be large, a check valve may be provided at the detergent inlet port to prevent water from flowing back into the detergent pipe.

Example four:

example four discusses the structure of the aeration washing chamber having the aeration washing process.

Fig. 3 is a schematic structural view of an aeration washing chamber provided in the fourth embodiment.

In fig. 3, the aeration washing chamber 1011 has: an inner bin 10111, an outer bin 10112 and an aeration mechanism 10113;

the inner bin body 10111 is provided with a through hole, and the inner side and the outer side of the inner bin body 10111 are communicated through the through hole;

the aeration mechanism 10113 is fixed at the bottom of the outer bin 10112;

the aeration means 10113 has an air outlet;

10113 the air outlet of the aeration mechanism faces the inner cabin 10111.

Therefore, the aeration mechanism provides compressed gas to form bubbles, and the bubbles float upwards to take away impurities in the sewage.

Fig. 1 shows that the sewage passes through the through-hole and penetrates the inside and outside of the inner container 10111, and the air bubbles generated by the aeration means 10113 also float upward from the outside of the inner container 10111 through the through-hole and overflow to the inside of the inner container 10111.

The compressed gas can contain ozone, so that the compressed gas can be washed by using the ozone, and the ozone also has the functions of sterilization and bleaching, so that the effects of sterilization and bleaching can be achieved while washing, and the aim of cleaning is fulfilled.

Further, the aeration mechanism in the fourth embodiment is explained.

The aeration mechanism 10113 is provided with an air suction pump and an aeration disc;

the aeration disc is provided with an air inlet and an air outlet, and the air outlet of the aeration disc forms an air outlet of the aeration mechanism 10113;

the air outlet of the air pump is communicated with the air inlet of the aeration disc.

Thus, the aeration mechanism can utilize the air pump to inject compressed gas into the washing bin.

Wherein, the air pump can be provided with a gas compressor.

Furthermore, the air pump can be provided with an ozone inlet and an air inlet, and the ozone inlet is provided with a valve for injecting ozone.

The air inlet of the air pump is communicated with the top of the outer bin body of the aeration washing bin through a pipeline.

Thus, the aeration mechanism can recycle the gas in the washing bin.

Ozone can increase the atomic oxygen content of the wash water, which will increase the effectiveness of and reduce the chemical detergent demand. Ozone can oxidize the dirt, making it easier to remove from the wash water. Ozone can reduce the need for harsh high PH chemical detergents traditionally used to remove fats, oils and greases FOG, and these detergents break the molecular bonds of the FOG into simple carbon-based molecular compounds, reducing the chemical detergent usage by about 25% to 50%. Of course, the actual amount of reduction will depend on the type of washing, the temperature, the current washing process and the design of the overall system of the laundry washing system used, and the use of ozone will also achieve a germicidal effect.

The ozone improves the use efficiency of the chemical detergent, reduces the need for high-temperature washing, and ensures that the washing process still has better washing effect at low temperature. Since the chemical detergent adheres to the fibers of the textile, a certain drying time is required, and washing with ozone can reduce the drying time by 20%.

Example five:

in the fifth embodiment, the washing chamber with the microwave washing function is explained, and the microwave agitator is added to the aeration washing chamber in the fourth embodiment.

Fig. 4 is a schematic structural view of an aeration washing chamber provided in the fifth embodiment.

In fig. 4, the aerated wash chamber 1011 also has a microwave shaker located at the bottom of the outer chamber body 10112 of the aerated wash chamber.

The high-frequency microwave generated by the vibration exciter can penetrate through the textile and can generate a 'cavitation' effect in water, and the 'cavitation' effect can generate nano-scale bubbles. Meanwhile, due to the generation of the cavitation effect, the dirt of the washed fabric is broken and falls off, and is dissolved in water and carried out of the water surface by the air bubbles. Meanwhile, due to the cavitation effect, the ozone can be decomposed to the maximum extent, and a large amount of atomic oxygen O is generated. The cavitation effect not only has the physical effect of the high-pressure impact force on the fabric, but also further plays the chemical function of ozone washing, and achieves the purpose of improving the washing capacity.

The high-frequency vibration signal is generated by the high-frequency microwave vibration exciter, and the high-frequency mechanical vibration is generated and propagated into the medium-cleaning solvent, and the vibration wave is radiated forwards in the cleaning liquid with the same density, so that the liquid flows to generate tens of thousands of nano-scale micro-bubbles. These bubbles form and grow in the negative pressure region where the excitation wave propagates longitudinally, and close rapidly in the positive pressure region. In the process of the cavitation effect, the closed micro-bubbles can form instant high pressure exceeding 1000 atmospheric pressure, and the instant high pressure is continuously generated like a series of small 'explosions' to continuously impact the surface of the textile, so that the dirt on the surface and in the gaps is rapidly peeled off, thereby achieving the purpose of purifying the surface of the object. The action mechanism mainly comprises the following aspects: because the cavitation bubbles generate strong shock waves when being broken, one part of the dirt layer is peeled off, dispersed, emulsified and fallen off under the action of the shock waves. Because bubbles generated by cavitation penetrate into gaps and gaps between a dirt layer and a surface layer formed by impact, the small bubbles expand and contract synchronously with wave pressure, physical force like peeling acts on the dirt layer repeatedly, the dirt layer is peeled layer by layer, and the bubbles continuously penetrate inwards until the dirt layer is completely peeled. This is a cavitation secondary effect.

The cleaning system described in the embodiment of the specification can utilize the aerated ozone and the microwaves generated by agitation to wash textiles, and because the ozone washing and the microwave washing are applied, the requirement of the washing on the temperature is low, even the heating is not needed, therefore, the low-temperature washing can be realized, the energy consumption is reduced, meanwhile, because the washing is carried out by utilizing various modes of the microwaves, the ozone and the detergent, the washing process is more efficient, and the method has the effects of high efficiency and energy saving.

Example six:

on the basis of the discussion of the washing chamber 101 of the first and second embodiments, the sixth embodiment describes the washing chamber with multiple stages connected in series in the second embodiment.

The multi-stage washing bin connected in series can be regarded as a washing unit with a plurality of basic washing bin bodies communicated in sequence.

As one embodiment, the washing bin is a multi-stage series washing bin, and comprises: a detergent washing bin and an aeration washing bin;

the detergent washing bin is communicated with the aeration washing bin to form the multistage serial washing bin.

The specific forms of the detergent wash tank and the aerated wash tank may be referred to the discussion of the various embodiments above.

Of course, the aeration washing bin can be an aeration washing bin with a microwave washing function.

Therefore, the system can also be provided with a microwave agitator which is fixed at the bottom of the outer chamber body of the aeration washing chamber.

Further, a pretreatment may be performed prior to washing, such that a pretreatment washing compartment is provided in the system, such that the pretreatment washing compartment, the detergent washing compartment and the aeration washing compartment are communicated to form a multi-stage series of washing compartments for textile treatment.

Furthermore, each washing bin in the multistage series washing bins can be provided with an inner bin body and an outer bin body, the inner bin bodies are positioned in the respective outer bin bodies, and the inner bin bodies can rotate so as to realize overturning during washing;

the rotating axes of the inner bin bodies are parallel, and meanwhile, in order to realize the conveying of the textiles in the multistage series washing bins, a conveying mechanism can be arranged between two adjacent washing bins in the washing bins of the multistage series washing bins.

The adjacent washing bins are provided with a bin door, when the bin door is opened, the adjacent bin bodies are communicated, and the conveying mechanism conveys the textiles in the previous bin body to the next bin body.

Example seven:

in order to achieve the same effect as that of the first embodiment, the embodiment of the present disclosure provides a method for cleaning textiles, in which the textiles are dehydrated between a washing process and a rinsing process, so that the textiles entering the rinsing process only carry a small amount of sewage, and thus, the method can reduce the number of times of rinsing or reduce the water injection amount of a single rinsing, and is more environment-friendly.

Fig. 5 is a schematic diagram of a method for cleaning textiles according to an embodiment of the present disclosure, which may include:

s501: and washing the to-be-washed clothes in the washing bin to obtain first washed clothes.

In particular, for the washing treatment of the laundry in the washing chamber, one or more of the above washing chambers may be used for washing, and in one embodiment, this may include one or more of S5011 to S5014:

s5011: and washing by utilizing a pretreatment washing bin.

And before the microwave washing and the aeration washing are carried out on the objects to be washed, carrying out dust removal prewashing on the objects to be washed. When the washing machine is used for washing, the textiles slide into the pretreatment washing bin through the funnel opening, are soaked quickly, and bring out dust, sandy soil and the like in the textiles, so that preparation is made for main washing.

S5011 as an alternative washing means may be provided before S5012 to S5014.

S5012: after water is injected into the washing bin, compressed gas is applied from the bottom of the washing bin by an aeration mechanism for aeration washing.

In S5012, the compressed gas may have ozone therein.

S5013: if the microwave shaker is disposed at the bottom of the washing chamber, S501 may include: to the washing chamber

After the water is washed, the microwave is applied by the microwave shaker to perform microwave washing.

In S5013, aeration washing and microwave washing may be performed, and therefore, an aeration mechanism may be further provided at the bottom of the washing chamber, and thus, S5103 may further include: and applying compressed gas from the bottom of the washing bin by using an aeration mechanism to carry out aeration washing.

S5104: in the washing with the detergent, water and the detergent may be mixed and then added to the washing tub before the aeration washing and the microwave washing are performed. This can be achieved by providing a detergent inlet opening in the wall of the inlet pipe of the detergent washing chamber, from which detergent is applied to the inlet pipe.

Alternatively, a timer may be provided to control the time of delivery of water and detergent to the washing chamber, such that mixing the water and detergent into the washing chamber may include:

a detergent inlet is arranged on the wall of a water inlet pipe of a detergent washing bin, and detergent is applied to the water inlet pipe through the detergent inlet after water supply is started.

S5015, comprehensive washing.

Injecting water and a detergent into the washing bin;

injecting compressed gas containing ozone into the washing bin from the bottom of the washing bin to generate bubbles below the liquid level, wherein the bubbles contain ozone and float to the liquid level to take away dirt and impurities and form foams on the liquid level, and the foams are not easy to break by a detergent, so that the impurities can be enriched on the liquid level and further not mixed into textiles;

the microwave masker is started to generate microwaves, a 'cavitation' effect can be generated in water, the 'cavitation' effect can generate nano-scale bubbles, dirt on the textile is broken down and falls off, the dirt is dissolved in the water and is taken out of the water surface by the bubbles, and meanwhile, due to the 'cavitation' effect, ozone can be decomposed to the maximum extent, and a large amount of atomic oxygen O is generated.

S502: and before rinsing, performing dehydration treatment on the first washings to obtain first dehydrate.

Of course, S502 may also perform other cleaning processes besides rinsing, and even perform washing again, and the specific washing manner may refer to the step in S501, which is not specifically described herein.

S503: and rinsing and dehydrating the first dehydrated product in sequence to obtain a second dehydrated product.

The textile is dehydrated between the washing process and the rinsing process, so that the textile entering the rinsing process only carries a small amount of sewage, and thus, the rinsing frequency can be reduced or the water injection amount of single rinsing can be reduced, and the method is more environment-friendly.

The activity of the conventional detergent is related to the temperature, so that when the conventional detergent is used for washing on one side, water needs to be heated before water is injected into a washing bin, and the cleaning method disclosed by the embodiment of the specification has the advantages that the ozone washing and the microwave washing are applied, so that the temperature requirement of washing is low, even heating is not needed, low-temperature washing can be realized, the energy consumption is reduced, meanwhile, the cleaning process is more efficient due to the fact that the washing is carried out in various modes of the microwave, the ozone and the detergent, and the method has the effects of high efficiency and energy saving.

Example eight:

on the basis of the seventh embodiment, the batch processing function is added, and the essence of batch processing is that, also because the time required by different cleaning links may be different, for example, the washing time is longer than the rinsing time, which makes the rinsing bin idle for a while, wasting the productivity, in order to enhance the cleaning of the textiles, a plurality of bins are provided for the same cleaning link, and the plurality of bins having the same cleaning function respectively process the textiles of the previous cleaning link at the same time.

In the seventh embodiment, S501 may be a mode of the first batch, and S503 may be a mode of the second batch, which are sequentially taken as examples to illustrate the time control of the batch.

The method may further comprise:

controlling the cleaning time of each cleaning link, comprising:

and setting the cleaning time of each cleaning link according to the number ratio of the bin bodies of each cleaning link.

The cleaning time of each cleaning link is in direct proportion to the number of the bin bodies of each cleaning link.

For example, the system has a washing bin, the washing bin needs 120s for washing, and the number of the washing bins is 2, at this time, the rinsing time can be set to be 120 × 2, namely 240s, and the washing bin conveys one washed textile to one of the two washing bins every 120s for rinsing; and after 120s, conveying one washed textile to the other rinsing bin for rinsing. Thus, the utilization efficiency of the productivity can be improved. Of course, this is only one and specific form of batch processing and is not specifically described herein.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. A textile cleaning system, comprising:

the washing bin, the first dewatering bin, the rinsing bin and the second dewatering bin;

the washing bin is provided with a textile feeding hole;

the first dewatering bin is provided with a textile feeding hole and a textile discharging hole;

a conveying mechanism is arranged between the textile feeding hole of the first dewatering bin and the textile discharging hole of the washing bin;

a conveying mechanism is arranged between the textile discharge port of the first dewatering bin and the textile feed port of the rinsing bin;

and a conveying mechanism is arranged between the textile discharge port of the rinsing bin and the textile feed port of the second dewatering bin.

2. A textile cleaning system as claimed in claim 1 wherein the washing chamber is a multi-stage series of washing chambers having: a detergent washing bin and an aeration washing bin;

the aeration washing bin is provided with an inner bin body, an outer bin body and an aeration mechanism;

the inner chamber body of the aeration washing chamber is provided with: the inner side and the outer side of the inner bin body of the aeration washing bin are communicated through the through holes;

the aeration mechanism is fixed at the bottom of the outer bin body of the aeration washing bin;

the aeration mechanism is provided with an air outlet;

the air outlet of the aeration mechanism faces the inner bin body of the aeration washing bin;

the detergent washing bin is communicated with the aeration washing bin to form the multistage serial washing bin.

3. A textile cleaning system as claimed in claim 2 further having a microwave agitator;

the microwave oscillator is fixed at the bottom of the outer bin body of the aeration washing bin.

4. A textile cleaning system as recited in claim 3, wherein the multi-stage tandem wash bin further has a pre-treatment wash bin;

the pretreatment washing bin, the detergent washing bin and the aeration washing bin are communicated to form a multi-stage serial washing bin for textile treatment.

5. The textile cleaning system of claim 4, wherein each bin body of the multistage series of washing bins has an inner bin body, the rotational axes of the inner bin bodies are parallel;

in the washing bins of the multistage series washing bins, a conveying mechanism is arranged between every two adjacent washing bins.

6. A textile cleaning system as claimed in claim 2 wherein the aeration mechanism has a suction pump and an aeration disc;

the aeration disc is provided with an air inlet and an air outlet, and the air outlet of the aeration disc forms an air outlet of the aeration mechanism;

and the air outlet of the air pump is communicated with the air inlet of the aeration disc.

7. The textile cleaning system of claim 6, wherein the air pump has an ozone inlet port and an air inlet port, the ozone inlet port having a valve thereon;

and an air inlet of the air pump is communicated with the top of the outer bin body of the aeration washing bin through a pipeline.

8. A textile cleaning system according to claim 1 wherein the wash bin is a detergent wash bin having a water inlet and a detergent feed inlet.

9. The textile cleaning system of claim 8, wherein the detergent wash tank further has a water inlet pipe and a detergent pipe;

the water inlet pipe is communicated with the detergent washing bin, and a water inlet is formed in the wall of the detergent washing bin;

the decontaminating agent pipe is communicated with the water inlet pipe, and a decontaminating agent inlet is formed in the pipe wall of the water inlet pipe.

10. A textile cleaning system as claimed in claim 1 wherein the first dewatering bin is a press dewatering bin or the first dewatering bin is a rotary dewatering bin.

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