WO2023003053A1 - Method for washing oil-impregnated dust cloth - Google Patents

Abstract

The present invention relates to a method for washing an oil-impregnated dust cloth, the method comprising: a primary washing step (S100) for primarily-washing a contaminated oil-impregnated dust cloth with water and a detergent; an oil input step (S200) for, in a wash tub containing the primarily-washed oil-impregnated dust cloth, inputting oil in a state where rinsing water has been inputted in the wash tub so that the oil-impregnated dust cloth is immersed therein; a spin-dry step (S300) for spin-drying by rotating the wash tub containing the primarily-washed oil-impregnated dust cloth, the water and the inputted oil; and a drying step (S400) for drying the spin-dried oil-impregnated dust cloth so as to remove moisture therefrom. The advantage is gained of enabling the oil, impregnated in the oil-impregnated dust cloth in order for dust adsorption, etc., to be very evenly distributed in woven fiber for the dust cloth.

Description

How to wash an oil rag

The present invention relates to a washing method for an oil mop used to clean the floor of a building, and more specifically, has the advantage of distributing the oil impregnated into the oil mop very evenly to the woven fibers for the mop for adsorption of dust. It relates to a method for washing oil rags.

A general oil mop is a kind of tool that cleans the floor by applying oil to woven fibers and wiping off dusty floors.

On the other hand, such an oil mop is used for dry cleaning the floor of a building on the principle of adsorbing various foreign substances or fine dust existing on the floor using oil components impregnated or applied to the mop.

In particular, due to the recent occurrence of various contagious diseases such as the new corona, sanitary management of multi-use facilities used by the public is becoming more important, and pathogenic microorganisms that may remain in the facilities are removed during hygiene management of these multi-use facilities. In order to prevent the propagation and maintenance of pathogenic microorganisms in facilities or facilities, it is required to perform sanitary management such as cleaning using antibacterial components as a dry cleaning method rather than a wet cleaning method.

On the other hand, these oily rags are reused as a method of newly absorbing oil through washing several times. Conventionally, in the washing process, after washing with water and detergent is completely finished, the washed rag is soaked in oil for adsorbing dust. Methods such as impregnation were used, but when the oil is absorbed into the mop by this method, the oil is not uniformly absorbed throughout the mop, so the oil absorbed by the mop adheres to the floor of the building where excess oil is absorbed. A problem occurred, and in a place where too little oil was absorbed, there was a problem in that the absorption efficiency of foreign substances such as dust present on the floor of a building was remarkably lowered.

In addition, Patent Document 1 below discloses an oil mop washing system and its washing method, but when washing an oil mop through the method disclosed in Patent Document 1, the oil newly absorbed into the mop is not uniform throughout the mop. As it is absorbed, when the floor of a building is cleaned using the washed oil mop, there is a problem in that the adsorption rate for dust on the floor is non-uniform, and as a result, the dust adsorption efficiency is also lowered.

Therefore, there is an urgent need to develop a new method for washing oily rags in which oil can be very uniformly distributed on the rag when washing and absorbing oil.

Patent Document 1: Korean Patent Publication No. 10-2004-0079295 (2004.09.14)

An object of the present invention is to provide a novel oil rag washing method in which oil can be very uniformly distributed on the rag when the oil rag is washed and the oil is newly absorbed.

An oil rag washing method according to an embodiment of the present invention includes a first washing step of first washing the contaminated oil rag with water and detergent (S100); An oil input step (S200) of injecting the oil in a state in which water for rinsing is input so that the oil cloth is submerged in the washing tub containing the oil cloth that has been washed first (S200); A dehydration step (S300) of performing dehydration by rotating the washing tub containing the firstly washed oil rag, water, and input oil; and a drying step (S400) of drying the dehydrated oil rag to remove moisture.

In the washing method for an oil mop according to an embodiment of the present invention, the oil input step (S200) is characterized in that it is performed in the last rinsing step of the first washing.

In the washing method of an oil mop according to an embodiment of the present invention, the dewatering step (S300) is characterized in that it is performed at a rotational speed of 1,000 to 1,200 rpm.

In the washing method of an oil rag according to an embodiment of the present invention, the drying step (S400) is characterized in that it is performed through natural drying using sunlight or hot air drying using a hot air blower.

The washing method of the oil mop according to the present invention includes a first washing step (S100) of first washing the contaminated oil mop with water and detergent; A steam treatment step of heating a mixed solution of water and oil to generate steam and spraying the generated steam to the firstly washed oil mop; An oil input step of injecting oil in a state in which water for rinsing is input so that the oil rag is submerged in the washing tub containing the primarily washed oil rag (S200); A dehydration step (S300) of performing dehydration by rotating the washing tub containing the primary washed oil rag, water, and the input oil; And a drying step (S400) of drying the dehydrated oil rag to remove moisture; to prevent the rag from drying while being hardened as the shape of the oil rag to be dried in the drying step is the same as the shape of the rag in which the drying was started. It is characterized in that it is carried out using a rotary dryer for the purpose.

The washing method of the oil mop according to the present invention has the advantage that the oil impregnated into the oil mop is very evenly distributed to the woven fibers for the mop for adsorption of dust.

1 is a process chart showing a schematic process of a washing method of an oil mop according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein.

The present invention relates to a washing method for an oil mop used to clean the floor of a building, and more specifically, has the advantage of distributing the oil impregnated into the oil mop very evenly to the woven fibers for the mop for adsorption of dust. It relates to a method for washing oil rags.

1 is a process chart showing a schematic process of a washing method of an oil mop according to the present invention.

Hereinafter, with reference to FIG. 1, a method for washing an oily mop according to the present invention will be described in detail.

An oil rag washing method according to an embodiment of the present invention includes a first washing step of first washing the contaminated oil rag with water and detergent (S100); An oil input step (S200) of injecting the oil in a state in which water for rinsing is input so that the oil cloth is submerged in the washing tub containing the oil cloth that has been washed first (S200); A dehydration step (S300) of performing dehydration by rotating the washing tub containing the firstly washed oil rag, water, and input oil; and a drying step (S400) of drying the dehydrated oil rag to remove moisture.

The first washing step (S100) is a process of first washing an oil rag contaminated by contaminants such as dust with water or water and detergent.

This first washing step (S100) can be performed using a conventional rotary washing machine equipped with a washing tub.

Such a first washing step (S100) may be carried out in a process in which rinsing, stirring, and dehydration processes are repeatedly performed several times.

After that, the oil input step (S200) is performed in the last rinsing step of the first washing step (S100).

The oil input step (S200) is a step of injecting the oil in a state in which water for rinsing is input so that the oil rag is submerged in the washing tub containing the oil rag washed through the above process.

That is, for the last rinse, the operation of the washing machine is stopped while maintaining a state in which water for the last rinse is put into the washing tub, and oil is injected into the water for the last rinse.

The oil is used to adsorb dust, which is a contaminant present on the floor of a building, etc., and for example, it is possible to use paraffinic oil such as GS Caltex's Kixx LUBO 2cSt.

At this time, the weight ratio of the last rinse water and paraffinic oil put into the washing tub is about 7:3 to 8:2.

That is, for example, when the last rinsing water put into the washing tub is 70 kg, it is possible to put 30 kg of paraffinic oil, or when the last rinsing water put into the washing tub is 80 kg, the paraffinic oil It is also possible to input 20 kg of silver.

Meanwhile, when the oil input step (S200) is completed in this way, the lid of the washing tub is closed and a dehydration process is performed.

The dewatering step (S300) is a process of performing dehydration by rotating the washing tub containing the primarily washed oil rag, water, and input oil.

At this time, the rotational speed of the washing tub may be 1,000 to 1,200 rpm.

This dehydration step (S300) is performed for about 5 to 10 minutes.

After this dehydration step (S300), about 70% of the mixed solution of water and oil is removed from the mop.

On the other hand, when the dehydration step (S300) is completed, a drying step (S400) described later is performed to remove moisture remaining in the mop.

The drying step (S400) is a process of drying the dehydrated oil rag to remove moisture, which can be performed through natural drying using sunlight or hot air drying using a hot air blower.

In this drying step (S400), for example, it is possible to perform natural drying by exposing to sunlight for 3 to 5 hours in a well-ventilated place.

In addition, the drying step (S400) may also be performed for 10 to 20 minutes in a hot air drying chamber equipped with a hot air blower to which hot air of 70 to 80 ° C is applied, for example.

When this drying step (S400) is performed, most of the moisture remaining in the mop is removed, and only oil components capable of adsorbing foreign substances such as dust remain in the mop.

In particular, in the case of using a method of injecting oil in a state in which water for rinsing is contained in a washing tub as in the present invention, an effect of very uniformly distributing oil throughout the mop can be obtained.

On the other hand, through such a drying process, it is possible to exert an effect of sterilizing the mop at a high temperature.

In particular, such hot air drying is preferably performed using a cylindrical rotary dryer having a rotatable cylinder.

In other words, when the mop is dried naturally using sunlight or by using non-rotating hot air drying, the mop hardens and dries in the same shape as the first dry mop, so the dried mop becomes hard. As a result, a problem in that adsorption capacity of contaminants such as dust is lowered may occur.

Therefore, it is possible to perform the drying process using a cylindrical rotary dryer having a rotatable cylinder in order to solve the problem of drying while maintaining a specific shape and deteriorating adsorption of contaminants.

Hereinafter, various experiments performed through Examples and Comparative Examples will be described in order to confirm the effectiveness of the method for washing oily mop according to the present invention.

<Example 1>

After putting the oil mop used to clean the floor of the building into the washing machine, and adding 100 g of detergent, the first washing was performed for 40 minutes. Then, in a state where 70 kg of the last rinse water was put into the washing tub of the washing machine, the operation of the washing machine was temporarily stopped, and 30 kg of GS Caltex's Kixx LUBO 2cSt was added. In this way, the washing machine was restarted in the state in which oil was added to perform rinsing and spin-drying. During spin-drying, the rotational speed of the washing tub was set to 1,000 rpm, and the spin-drying process was performed for about 10 minutes. Thereafter, in a state where it was placed in a chamber capable of hot air drying, hot air at 80 ° C. was applied for 15 minutes to remove moisture remaining in the mop.

<Example 2> - Addition of sodium carbonate

After putting the oil mop used to clean the floor of the building into the washing machine, and adding 100 g of detergent, the first washing was performed for 40 minutes. Then, in a state where 70 kg of the last rinse water was put into the washing tub of the washing machine, the operation of the washing machine was temporarily stopped, and 30 kg of Kixx LUBO 2cSt from GS Caltex and 50 g of sodium carbonate were added. In this way, the washing machine was restarted in the state in which oil was added to perform rinsing and spin-drying. During spin-drying, the rotational speed of the washing tub was set to 1,000 rpm, and the spin-drying process was performed for about 10 minutes. Thereafter, in a state where it was placed in a chamber capable of hot air drying, hot air at 80 ° C. was applied for 15 minutes to remove moisture remaining in the mop.

<Example 3> - Addition of high-temperature steam treatment process

After putting the oil mop used to clean the floor of the building into the washing machine, and adding 100 g of detergent, the first washing was performed for 40 minutes. Take out the oil mop after the first washing, and generate high-temperature steam of about 150℃ using a mixed solution in which water and Kixx LUBO 2cSt from GS Caltex are mixed in a weight ratio of 1:1. Steam was evenly sprayed on the oil mop after the first washing for about 5 minutes, and the oil mop after this high-temperature steam treatment was cooled to 60 ° C and put back into the washing tub, and 70 kg of the final rinse water was put into the washing tub of the washing machine In the finished state, the operation of the washing machine was temporarily stopped, and 30 kg of Kixx LUBO 2cSt from GS Caltex was introduced. In this way, the washing machine was restarted in the state in which oil was added to perform rinsing and spin-drying. During spin-drying, the rotational speed of the washing tub was set to 1,000 rpm, and the spin-drying process was performed for about 10 minutes. Thereafter, in a state where it was placed in a chamber capable of hot air drying, hot air at 80 ° C. was applied for 15 minutes to remove moisture remaining in the mop.

<Comparative Example 1> - Oil was added after washing was completed

After putting the oil mop used to clean the floor of the building into the washing machine, and adding 100 g of detergent, the first washing was performed for 40 minutes. Thereafter, 70 kg of the last rinse water was put into the washing tub of the washing machine, and the washing machine was operated to perform rinsing and spin-drying. During spin-drying, the rotational speed of the washing tub was set to 1,000 rpm, and the spin-drying process was performed for about 10 minutes. Then, in a state where it was placed in a chamber capable of hot air drying, hot air at 80 ° C was applied for 15 minutes to remove the remaining moisture in the mop, and the oily mop from which the moisture was removed was impregnated with GS Caltex's Kixx LUBO 2cSt. After that, dehydration and drying were performed. During dehydration, the rotational speed of the washing tub was 1,000 rpm, and the dehydration process was performed for about 10 minutes. On the other hand, drying was performed for 15 minutes with hot air at 80 ° C. in a state in which hot air drying was possible.

[Experiment 1] - Oil distribution measurement experiment

An experiment was performed to measure the distribution uniformity of the oil distributed on the mop using the oil mop washed through Examples 1 to 3 and Comparative Example 1. The experiment was carried out by selecting 7 identical points of the oil rag washed through Examples 1 to 3 and Comparative Example 1, respectively, and measuring the amount of oil (g/cm 2 ) absorbed at each location, The results are shown in Table 1 below.

division	Branch 1	branch 2	Branch 3	Branch 4	Branch 5	Branch 6	Branch 7
Example 1	3.52	3.51	3.52	3.50	3.51	3.52	3.51
Example 2	3.85	3.84	3.85	3.85	3.85	3.84	3.85
Example 3	3.98	3.98	3.97	3.99	3.98	3.98	3.99
Comparative Example 1	2.87	2.51	3.87	4.55	0.57	5.22	2.41

(Unit: g/cm²)

[Experiment 2] - Measurement of dust adsorption efficiency

Using the oily mop washed through Examples 1 to 3 and Comparative Example 1, an experiment was performed to measure the dust absorption efficiency of the mop. The experiment was conducted by selecting 7 identical points of the oily mop washed through Examples 1 to 3 and Comparative Example 1, respectively, and measuring the amount of dust (g/cm 2 ) adsorbed to each location. The results are shown in Table 2 below.

division	Branch 1	Branch 2	Branch 3	Branch 4	Branch 5	Branch 6	Branch 7
Example 1	2.87	2.85	2.75	2.82	2.80	2.70	2.71
Example 2	3.54	3.50	3.42	3.51	3.42	3.44	3.58
Example 3	4.24	4.51	4.35	4.36	4.43	4.48	4.50
Comparative Example 1	1.53	1.33	2.88	2.99	0.21	2.87	1.47

(Unit: g/cm²)

Claims (3)

1. A first washing step of first washing the contaminated oil rag with water and detergent (S100);

   A steam treatment step of heating a mixed solution of water and oil to generate steam and spraying the generated steam to the firstly washed oil mop;

   An oil input step (S200) of injecting oil in a state in which water for rinsing is input so that the oil rag is submerged in the washing tub containing the primarily washed oil rag (S200);

   A dehydration step (S300) of performing dehydration by rotating the washing tub containing the primary washed oil rag, water, and the input oil; and

   A drying step (S400) of drying the dehydrated oil rag to remove moisture;

   The washing method of the oil rag, characterized in that the drying step is performed using a rotary dryer to prevent the rag from drying while hardening as the shape of the rag in which the first drying is initiated.
2. The method of claim 1,

   The oil rag washing method, characterized in that the oil input step (S200) is performed in the last rinsing step of the first washing step.
3. The method of claim 1,

   The dehydration step (S300) is a method of washing an oil rag, characterized in that carried out at a rotational speed of 1,000 to 1,200 rpm.

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