KR102652973B1 - Eco-friendly backpack made from recycled PET - Google Patents

Abstract

The eco-friendly backpack consists of a backpack main body, a shoulder rest, and an air injection and discharge type variable partition device installed inside the backpack main body. An opening and closing means for opening and closing is formed on the backpack main body, and an upper circumference of the inner surface of the backpack main body is provided. One fixing device is formed, and the air injection and discharge type variable partition device includes a first wall, a second wall, and the first and second walls on which a second fixing device that is detachably coupled to the first fixing device is installed. It consists of a number of variable partition walls installed between them.

Description

Eco-friendly backpack made from recycled PET}

The present invention relates to a backpack, which is manufactured using recycled PET, an eco-friendly material, and also relates to an eco-friendly backpack manufactured using recycled PET, which can efficiently use storage space.

A backpack refers to a type of bag worn around the back, and in recent years it has been widely used as a briefcase for office workers.

Until about 10 years ago, most office workers used portable office bags, but as the office environment gradually changed, office workers started carrying items other than documents in their office bags, such as portable IT devices such as laptop computers. Such portable IT devices have the disadvantage of being quite heavy when stored in an office bag and causing fatigue.

Accordingly, office workers used lightweight hiking backpacks or student bags to store documents and portable IT devices. However, in the case of lightweight mountaineering backpacks or student bags, there was a problem that efficient storage was difficult because the bags were manufactured for the purpose of storing many contents, such as mountaineering supplies or books. Accordingly, backpacks for efficiently and safely storing documents and portable IT devices have been developed, released on the market, and are currently in use.

Although these various backpacks are sold, a lot of effort has been made to improve user convenience in that they are mainly used on the back.

Republic of Korea Patent Registration No. 10-2423665 (2022.07.20) proposes a “backpack with a tightness adjustment mechanism,” and the prior art backpack has a variably applied shoulder strap shoulder structure to provide a tight fit depending on the usage status of the backpack. The emphasis is on making it usable by changing it.

In addition, Republic of Korea Patent Publication No. 10-2023-0135147 (2023.09.22) relates to “backpack,” and its purpose is to improve the user’s posture.

The prior art backpacks described above are only about user convenience and do not suggest any improvements to increase the storage efficiency of the backpack. In general, the storage structure of the backpack is similar to the previously commonly used briefcase, with a separate compartment to store documents and IT devices separately, and a pocket storage box to separately store mobile phones and other small items. The wall section is installed. However, even with these separate compartments, it was difficult to store items efficiently. For example, IT devices are stored in a dedicated storage area, and small-sized items are stored in a pocket storage box, but a large amount of documents and various items, such as glasses cases, are stored mixed together. , there were often times when it was difficult to easily find the desired item in the backpack later. In addition, when fragile items or easily scratched items are stored together, the problem of item damage may occur. However, to date, a backpack that easily and safely stores items has not been provided.

Meanwhile, most of the currently commercialized backpacks are manufactured using synthetic fiber, that is, PET, a type of petroleum-based plastic fiber. Petroleum-based plastic fibers do not decompose well when disposed of, so it takes about 100 to 500 years to completely decompose. Additionally, there is a disadvantage that incineration or landfilling can cause environmental problems such as endocrine disruptors or air pollution.

Meanwhile, polyester fiber used in the manufacture of backpacks is widely used because it not only has excellent physical properties, but also has a generalized dyeing process and can be used as a material for various types of textile products such as cloth and bags. Because microorganisms multiply on fibers due to human sweat and external contamination, a large amount of ammonia is generated, causing unpleasant odors and harmful problems to the human body. In particular, the handles of bags that are frequently touched are not only difficult to wash, but are also highly susceptible to contamination by substances such as sweat. Additionally, in the case of medical textile materials, if bacteria or viruses remain, there is a high risk of serious secondary infection and spread of disease.

Patent Document 1: Republic of Korea Patent Registration No. 10-2423665 (2022.07.20) Patent Document 2: Republic of Korea Patent Publication No. 10-2023-0135147 (2023.09.22)

The purpose of the present invention is to improve the storage capacity and to have a structure that can safely store and store items, and to have high antibacterial performance so that copper nanoparticles are uniformly distributed throughout the entire recycled PET fiber, and to maintain the antibacterial effect for a long time while maintaining the tensile strength of the PET fiber. The goal is to provide an eco-friendly backpack made of recycled PET fiber with performance that does not reduce strength.

In order to achieve the purpose of the present invention, an eco-friendly backpack manufactured using recycled PET according to the present invention is composed of a backpack body, a shoulder rest, and an air injection and discharge type variable partition device installed inside the backpack body, and the backpack body An opening and closing means for opening and closing is formed, and a first fixing device is formed around the upper periphery of the inner surface of the backpack main body, and the air injection and discharge type variable partition device is a second fixing device that is detachably coupled to the first fixing device. It consists of a first wall on which the device is installed, a second wall, and a plurality of variable partition walls installed between the first and second walls, and an air control device is installed at one end of the variable partition wall devices, and the first wall is installed. An air flow path is installed at the top of the wall, the variable partition walls are fixed to the first wall by connecting the air control device to the air flow path, and the two outermost variable partition wall devices among the variable partition wall devices are The other end is fixed to the second wall, and by injecting air into the air distribution path and the air control device, the variable partition wall expands to widen the gap between the first wall and the second wall, thereby forming a storage space between the variable partition walls. The eco-friendly backpack is made of recycled PET fiber made from recycled PET composite containing copper nanoparticles and is characterized by having antibacterial properties.

In the eco-friendly backpack manufactured using recycled PET according to the present invention, the air injection and discharge type variable partition wall has two elastic resin films placed facing each other on the inside, and a fiber fabric is attached to the outer surface of each elastic resin film using an adhesive means. It is characterized by forming a sewing line by sewing fibers at predetermined intervals in the horizontal and vertical directions, and sealing the entire outer peripheral surface with resin.

In the eco-friendly backpack according to the present invention, a plurality of rod shapes (E) are formed by the sewing lines.

In the eco-friendly backpack according to the present invention, the first and second fixing means are characterized in that they are Velcro non-woven fabric.

In the eco-friendly backpack according to the present invention, the variable partition walls can be selectively inflated by controlling air injection through an air control device connected to each of the variable partition walls.

In the eco-friendly backpack according to the present invention, the sewing line is formed by ultrasonic bonding the elastic resin film using an ultrasonic bonding means.

In the eco-friendly backpack according to the present invention, the size of the rod shape expanded by air can be adjusted by adjusting the spacing between sewing lines.

In the eco-friendly backpack according to the present invention, the copper nanoparticles contained in the recycled PET fibers have a size distribution of 1 to less than 500 nm, and are manufactured in an aqueous solution or organic solvent phase, or a mixed solvent thereof using terephthalic acid as a stabilizer, It is characterized by manufacturing recycled PET fibers using copper nanoparticles made into a dried phase through a freeze-drying process.

In the eco-friendly backpack according to the present invention, copper nanoparticles are mixed with recycled PET fibers in a weight ratio of 0.01% to less than 7.5%.

The eco-friendly backpack manufactured using recycled PET according to the present invention has an air injection and discharge type variable partition wall that is inflated with air inside the storage part, thereby forming a plurality of storage parts by inflating the variable partition wall with air when used. This has the effect of facilitating the storage of goods and achieving efficient storage of goods along with user convenience.

In addition, the eco-friendly backpack manufactured using recycled PET according to the present invention can efficiently cope with environmental problems because it is composed of fibers made of recycled PET, an eco-friendly material, while the PET fiber contains copper nanoparticles as an antibacterial composition. By distributing copper nanoparticles evenly throughout the entire single fiber, copper nanoparticles exist uniformly within the fiber so that antibacterial properties can be displayed evenly throughout, and dopamine added as a stabilizer binds strongly to the regenerated PET fibers, allowing the copper nanoparticles to remain in the regenerated PET fibers. By binding strongly to the recycled PET fibers, the copper nanoparticles do not aggregate and are distributed evenly throughout the entire surface, resulting in excellent antibacterial properties. The tensile strength of the recycled PET fibers does not deteriorate, making it possible to provide a backpack that is eco-friendly and has excellent antibacterial properties. It works.

Figure 1 is a perspective view schematically showing the appearance of an eco-friendly backpack manufactured using recycled PET according to the present invention.
Figure 2 is a cross-sectional view of the backpack body cut along line AA, showing the internal configuration of the eco-friendly backpack.
Figures 3A and 3B are diagrams showing the configuration of an air injection and discharge type variable partition device used in an eco-friendly backpack according to the present invention.
Figure 4 is a side view showing the operation of the variable partition wall of the air injection and discharge type variable partition device according to the present invention.
Figure 5 is a view showing how the variable partition wall of the air injection and discharge type variable partition wall device operates according to air injection within the backpack main body according to the present invention.
Figure 6 is a diagram showing an example of configuring a plurality of hydraulic parts inside an eco-friendly backpack with the variable partition wall of the air injection and discharge type variable partition device according to the present invention.
Figure 7 is a diagram schematically showing an example of a device configuration for injecting or discharging air into an air injection and discharge type variable partition according to the present invention.
Figure 8 is a surface chemical structure diagram of copper nanoparticles prepared using a stabilizer according to the present invention.
Figure 9 is a photograph of a solution of copper nanoparticles prepared using a stabilizer according to the present invention and a transmission electron microscope photograph.
Figure 10 is a scanning electron micrograph of a fiber containing copper nanoparticles prepared according to the present invention.
Figure 11 is a photo of the antibacterial effect of PET fibers manufactured according to the present invention and PET fibers containing copper nanoparticles.

Hereinafter, preferred embodiments according to the present invention will be described in more detail with reference to the attached drawings.

Prior to the description of the present invention, the following specific structural and functional descriptions are merely illustrative for the purpose of explaining embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. , should not be construed as being limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in this specification. However, this is not intended to limit the embodiments according to the concept of the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Figure 1 is a diagram showing the overall appearance of an eco-friendly backpack 100 manufactured using recycled PET according to the present invention.

While the eco-friendly backpack shown in Figure 1 has the external shape of a typical backpack, it is obvious that the external shape can change depending on the situation. As shown in Figure 1, the backpack is composed of a backpack main body 10 to store items and a shoulder hanger 20 to hang on the user's shoulder, and the backpack main body is equipped with an opening and closing means such as a jack for opening and closing a plurality of main bodies. (11) is formed. If there is a fixed partition in the backpack main body to form two storage spaces, two opening and closing means are needed as shown in Figure 1, but if there is only one storage space, only one opening and closing means is needed. Additionally, although not shown in the drawing, an external storage box for storing small items may be installed on the outer surface of the backpack main body.

Since the characteristic feature of the eco-friendly backpack manufactured using recycled PET according to the present invention is the internal storage part of the backpack main body, the description will focus on the internal storage part.

FIG. 2 is a cross-sectional view of the backpack body cut along line A-A in FIG. 1.

In a typical backpack, there is usually nothing inside the front part 21 of the main body, but in the present invention, an air injection and discharge type variable partition device, which will be described in detail later, is installed. In FIG. 2, reference number 22 is a first fixing means for fixing the variable bulkhead in a detachable manner. It is preferable that the fixing means is made of Velcro non-woven fabric with a detachable function, but it should be noted that other means with a detachable function can be used.

Figure 3A (a) is a perspective view showing the configuration of the air injection and discharge type variable partition device according to the present invention, (b) is a side view seen from direction B, and Figure 3B is a side view seen from direction B in Figure 3A.

3A to 3B, the air injection and discharge type variable partition device 30 according to the present invention includes a flexible first wall 31 and a second wall 32, between the first wall and the second wall. It is arranged and consists of a variable partition wall body 33 that forms a partition wall through expansion and contraction.

Figure 3A shows a state in which the variable partition wall 33 is expanded, and a plurality of variable partition walls 33 are installed between the first wall 31 and the second wall 32. Each of the plurality of variable partition walls 33 is connected to an air passage 34 installed on the upper part of the first wall 31, and air is injected and expanded through this air passage or air is discharged. This causes contraction. The air distribution path 34 and each of the variable partition walls 33 are connected through a switch-type air disconnection device 35. The air control device 35 controls the air supplied to or discharged from the variable partition wall 33 in the air distribution path 34 to individually expand or contract the variable partition wall body.

(b) in FIG. 3A is a side view seen from (a) to direction B, showing the back of the first partition 31, that is, the portion facing the front inner side 21 of the backpack main body 10. As shown in the drawing, a second fixing device 31' is installed on the top of the back of the first wall 31. The second fixing device is combined with the first fixing device 22 installed on the front inner side 21 of the backpack main body and serves to fix the air injection and discharge type variable partition device within the backpack main body.

Figure 3B is a side view seen from direction A in Figure 3A, showing the specific configuration of the air injection and discharge type variable partition device according to the present invention.

As shown in Figure 3B, the air injection and discharge type variable bulkhead device according to the present invention includes a first wall 31 fixed to the front inner side of the backpack main body, an air distribution path 34 installed on the upper part of the first bulkhead, and , It is connected to the air distribution path 34 through an air control device 35 and is composed of a variable partition wall 33 connected to the first wall 31. A second fixing device 31' for coupling with the first fixing device 22 is installed on the upper surface of the first wall 31, and on the other side, it controls the expansion and contraction of the variable partition wall 33. For this purpose, an air distribution path 34 is fixedly installed to supply or discharge air. The variable partition wall 33 is fixedly installed in the air distribution path 34 through an air disconnection device 35 installed at one end of the variable partition wall 33. The first fixing device and the second fixing device are easily attachable and detachable fixing devices and may be made of, for example, non-woven Velcro. However, any configuration, such as buttons or snap buttons, can be used as long as attachment and detachment can be achieved.

The cross-sectional configuration of the variable partition wall 33 is shown in the circular excerpt of FIG. 3B. The cross section is a cross section of a circular portion taken from Figure 3B, viewed in the D direction.

Two elastic resin films (31'1) are placed facing each other on the innermost side, and a fiber fabric (31'2) is attached to the outer surface of each elastic resin film (31'1) using a predetermined adhesive means. Then, a sewing line 31'3 is formed by sewing using fibers in the horizontal and vertical directions at predetermined intervals. Accordingly, an external shape in which a plurality of rod shapes E are stacked with seam lines 31'3 is formed on the outer surface of the variable partition. As will be explained later, each of the rod shapes (E) is inflated into a rod shape by injecting air, and since air can be discharged through the marks pierced by the needle during sewing, it is better to seal the needle marks with resin. need.

Meanwhile, instead of forming the sewing line 31'3 using fiber threads, the rod shape (E) can be formed by forming the sewing line 31'3 by bonding the elastic resin film using an ultrasonic adhesive means. , when forming a rod shape, the rod shape is formed by leaving a gap in the sewing line that allows air to communicate between each rod shape. When forming a grid pattern using ultrasonic adhesive means, the creation of needle marks that occur when using sewing thread is prevented and separate sealing treatment is not required. Meanwhile, since air is injected or discharged from each of the rod shapes through a separate passage, it is not necessary to communicate between the rod shapes.

Meanwhile, in the present invention, when the variable partition wall 33 expands by injection of air or contracts due to discharge of air, the second wall 32 must move away from or get closer to the first wall 31. Among the plurality of variable partition walls 33 between the first wall and the second wall, the two variable partition walls 33 disposed at the outermost sides on both sides must be fixed to the second wall 32.

The operation of the air injection and discharge type variable partition device according to the present invention, configured as described above, is as follows.

First, when the air is completely discharged from the variable partitions between the first wall and the second wall, as shown in (a) of FIG. 4, the variable gap between the first partition 31 and the second partition 32 The wall 33 is contracted so that the first partition and the second partition come into close contact with each other. In this state, when air is injected through the air distribution path 34, the air is injected into the variable partition wall 33 through the air control device 35, and the air injected into the variable partition wall is injected into the air induction path ( It is injected into each rod shape (E) through F). Then, as shown in (b) of FIG. 4, the variable partition walls gradually expand, that is, swell into a rod shape, widening the gap between the first and second partition walls.

When sufficient air is injected into each rod shape (E) through the air induction path (F), the variable bulkhead is fully expanded, and as shown in (c) of FIG. 4, there is a gap between the first and second bulkheads. As the gap widens to the maximum, a space for storing items is created between the plurality of variable partitions between the first and second partitions. At this time, since the seam line 31'3 between the rod shapes E does not swell, the rod shape E has a nearly circular cross-sectional shape. If the gap between the sewing lines 31'3 is large, the expansion volume increases when the rod shapes expand, ultimately reducing the volume of the storage space. Therefore, if the spacing between the sewing lines is made dense, when the rod shapes expand, the expansion volume becomes relatively small, which not only increases the volume of the storage space, but also strengthens the supporting force of the variable partition wall, thereby increasing the storage space. Items stored in are stored more stably.

Figures 5 and 6 show various embodiments in which the air injection and discharge type variable partition device 30 is installed and operated within the backpack main body 10. Figures 5 and 6 show a top view of the backpack body with the air injection and discharge type variable partition device 30 installed.

First, referring to Figure 5, it shows the operation of the air injection and discharge type variable partition device 30 within the backpack main body 10.

First, Figure 5 (a) shows that the air injection and discharge type variable partition wall device 30 installed in the backpack main body is in an inoperative state, that is, the air in the variable partition wall 33 is completely discharged and is in a contracted state. At this time, in the drawing, there is a certain gap between the first wall 31 and the second wall 32, but in reality, they are in contact with each other. In this contracted state, when air is injected through the air flow path 34 and the air control device 35 of each of the variable partition walls 33 connected to the air flow path, the injected air is inside the variable partition wall 33. It moves along the air induction path (F) and is injected into the rod shape (E) of the variable partition wall, and the rod shape gradually expands, that is, swells, forming the first wall and the second wall as shown in (b) of FIG. The gap between the two walls gradually becomes distant. In this state, when enough air is injected into the variable partition wall 33 and the rod shape E has a perfect shape, the gap between the first wall and the second wall is as shown in (c) of Figure 5. The backpack body is expanded to completely fill the interior, and at the same time, a plurality of storage spaces formed by the variable partition walls 33 are created.

In the storage spaces created in this way, goods are stored according to type, purpose or size, and since the variable partition walls are inflated with air, they have elasticity, so damage due to interference between stored goods can be prevented.

On the other hand, when it is desired to return the air injection and discharge type variable bulkhead device (30) installed in the backpack main body to its initial state, that is, when it is desired to completely discharge the air from the variable bulkhead of the variable bulkhead device and place it in a deflated state, the air control device (35) ) and the air distribution path 34, the rod shape (E) of the variable partition shrinks and the gap between the first wall and the second wall gradually becomes closer, ultimately reaching (a) in Figure 5. The state is shown. At this time, as explained above, since the two variable partition walls 33 disposed at the outermost part are connected to the second wall, when the variable partition wall contracts, the two walls also move toward each other.

The variable partition walls 33 of the air injection and discharge type variable partition device 30 according to the present invention are not connected to the second wall except for the two outermost variable partition walls connected to the second wall, so their movement is limited. free. That is, by controlling air injection into the variable partitions connected to the second wall, the number and size of storage spaces formed by the variable partitions can be adjusted.

An example of forming a storage space will be described with reference to FIG. 6 as follows. In the drawing, a total of six variable partition walls (33a - 33f) are shown, and the outermost two variable partition walls (33a, 33b) are connected to the second wall (32), and the remaining variable partition walls (33c - 33f) are connected to the second wall (32). It is not connected to the second wall.

Figure 6 (a) shows that all the variable partition walls 33a - 33f are inflated with air to form a total of five storage spaces (1 - 5). Among the variable partition walls, air is always injected into the outermost two variable partition walls (33a, 33b) to expand them.

Figure 6 (b) shows the remaining variable partition walls 33a, 33b, and 33d in a state in which air is not injected into the variable partition wall 33c by operating the air control device 35 connected to the variable partition wall 33c. , 33e, 33f) are created by expanding them with air to create four storage spaces (1' - 4'). Since the storage space 1' has a larger space than the remaining storage spaces, it can store large items. Figure 6(c) shows three storage spaces (1" - 3") formed by preventing air from being injected into the variable partition walls 33d and 33e, and Figure 6(d) shows the variable partition walls 33d and 33e. (33c - 33e) shows that only two storage spaces (1.1, 1.2) were created by blocking air injection. In this way, since it is possible to form a storage space by inflating only the selected variable partitions with air using the air blocking device 35, it is possible to form storage spaces of various sizes depending on the size and type of the article, etc. When storage space is not needed, air is discharged from the variable partition walls to shrink the variable partition walls, so that the air injection and discharge type variable partition device can be maintained on the inner side of the backpack body with a minimum volume.

Meanwhile, a configuration for injecting or discharging air into the variable partition wall 33 is shown in FIG. 7.

In order to inject or discharge air into the variable partition wall 33, one end of the air hose 34' is connected to one end of the air distribution path 34, and the other end of the air hose is connected to the air pump 40. The air hose and air pump can be fixedly installed at a predetermined location on the backpack, but the air hose and air pump can be manufactured separately and used by connecting to the air distribution path 34 only when necessary.

However, since the small air pump 40 has a built-in battery and weighs approximately 480 g or more, it can give the user a significant sense of weight when fixed to a backpack. Therefore, only an air pump with a pumping function can be fixed to the backpack, and if necessary, the air pump can be operated using the portable battery 60. Additionally, a separate, independent control panel 50 can be connected to the air pump.

Another object of the present invention is to manufacture an eco-friendly backpack according to the present invention using recycled polyester (PET) fiber, which has antibacterial properties and maintains antibacterial properties for a long time, but does not deteriorate physical properties such as tensile strength. .

In general, bags worn on the shoulder, such as backpacks, are highly likely to become contaminated as they are exposed to various external environments while worn for long periods of time, so excellent waterproofing and antibacterial performance are required. In particular, the durability of the backpack can be further reduced due to the presence of various bacteria and molds that exist in the natural environment. Accordingly, the eco-friendly backpack according to the present invention is manufactured from recycled PET fibers that exhibit antibacterial performance by uniformly distributing copper nanoparticles, which are an antibacterial composition, throughout the entire section of the single fiber and at the same time do not deteriorate durability such as tensile strength.

The production of recycled PET fiber used in the production of an eco-friendly backpack made using recycled PET according to the present invention consists of synthesis of copper nanoparticles and a PET fiber manufacturing process containing copper nanoparticles, and additionally PET fiber Evaluation of the dispersion state of copper nanoparticles, measurement of tensile strength, and evaluation of antibacterial activity were conducted. Since the production of textile fabric using the recycled PET fiber is a widely known process, detailed description thereof is omitted in the present invention.

1. Synthesis of copper nanoparticles.

Example 1:

1.0 g of copper(II) sulfate pentahydrate (CuSO ₄ ·5H ₂ O) was completely dissolved in 500 ml of distilled water, then 0.1 g of polyethylene glycol (PEG) was added and stirred at room temperature for 30 minutes. 0.01 g of terephthalic acid and 0.01 g of dopamine (Dopamine HCl, aldrich) were added and stirred for additional 10 minutes. To adjust pH and accelerate the reduction reaction, sodium hydroxide (NaOH) solution was added to adjust pH to 9.0. Sodium borohydride (NaBH ₄ ), a reducing agent, was added and stirred for 30 minutes to synthesize a dark red solution. After the reaction was completed, 500 ml of ethanol was added to create a 1:1 solution of alcohol and distilled water, and centrifugation and redispersion were repeated three times. After centrifugation three times, 500 ml of distilled water was added and dispersed, and then freeze-drying was performed for 3 days to obtain dry copper powder. Terephthalic acid and Dopamine, which were used as stabilizers, were combined on the surface of the obtained copper nanoparticles as shown in Figure 8. Strong surface bonding is expected depending on the covalent coordination bond between the transition metal and oxygen and nitrogen atoms. The prepared copper nanoparticle solution has a dark yellow color as shown in Figure 2, and as a result of transmission electron microscopy analysis, it was confirmed to have a size of about 100 nm or less.

Example 2:

1.0 g of copper(II) sulfate pentahydrate (CuSO ₄ ·5H ₂ O) was completely dissolved in 500 ml of distilled water, then 0.1 g of polyethylene glycol (PEG) was added and stirred at room temperature for 30 minutes. 0.01 g of terephthalic acid was added and stirred for an additional 10 minutes, and to adjust pH and accelerate the reduction reaction, sodium hydroxide (NaOH) solution was added to adjust pH to 9.0. Sodium borohydride (NaBH ₄ ), a reducing agent, was added and stirred for 30 minutes to synthesize a dark red solution. After the reaction was completed, 500 ml of ethanol was added to create a 1:1 solution of alcohol and distilled water, and centrifugation and redispersion were repeated three times. After centrifugation three times, 500 ml of distilled water was added and dispersed, and then freeze-drying was performed for 3 days to obtain dry copper powder. Terephthalic acid and Dopamine, used as stabilizers, are combined on the surface of the obtained copper nanoparticles as shown in Figure 1. Strong surface bonding is expected depending on the covalent coordination bond between the transition metal and oxygen and nitrogen atoms. The prepared copper nanoparticle solution has a dark yellow color as shown in Figure 9, and as a result of transmission electron microscopy analysis, it was confirmed to have a size of about 100 nm or less.

2. Manufacturing PET fibers containing copper nanoparticles.

The melting temperature of PET granules (6201D fiber, Naturework, USA) was 170 °C and the spinning temperature was 190 °C. Using a micro-compounder, nanocomposite fibers were spun with a combination of 10 g of PET granules and 0.05 g, 0.1 g, 0.5 g, 0.75 g, and 1.0 g of copper nanoparticles prepared according to Example 1 or Example 2. . Before spinning, PET granules are dried at 80°C under 5% moisture for 24 hours. Mix in a micro-compounder at 190°C and 100 rpm for 15 minutes. It was spun through a spinneret (D = 0.8 mm) and manufactured at a constant stretching ratio. In this way, PET fibers containing 0.5%, 1%, 5%, 7.5%, and 10% of copper nanoparticles by weight were manufactured.

3. Evaluation of dispersion state of copper nanoparticles in PET fiber.

The fiber surface and cross-section were analyzed using a Jeol JSM 5310, scanning electron microscope, at an acceleration voltage of 10 kV. The photograph shown in Figure 10 is a cross-sectional scanning microscope (SEM) photograph of a PET fiber containing 5% of copper nanoparticles prepared according to Example 1. As observed in the photograph, the copper nanoparticles are uniformly distributed in the fiber. You can confirm that it exists.

4. Tensile strength measurement.

The tensile strength measurements for the recycled PET fibers manufactured as above were as follows.

The physical properties of PET fibers containing copper nanoparticles prepared according to Example 1 were measured in accordance with ASTM D3822-07 using an Instron 5567 tensile tester. The fiber was cut to 25 mm in length, inserted on both sides into the tensile strength tester clip, and pulled at a speed of 100 mm min-1 until it broke to obtain the stress-strain curve and initial modulus of elasticity. As shown in Table 1 below, the analysis results show that when the weight ratio of copper nanoparticles is increased to 5%, there is a significant difference in the properties related to tensile strength, such as breaking stress, breaking strain, and initial elastic modulus, compared to the case without copper nanoparticles. I confirmed that it wasn't there. However, when increasing to 7.5& or more and 10%, a significant decrease in breaking stress, breaking strain, and initial elastic modulus was observed.

PET fiber (copper nanoparticles %) Breaking stress (MPa) Breaking strain (%) Initial elastic modulus (GPa) 0% 76.1 43.2 2.1 0.05% 76.5 42.3 2.2 One% 75.4 41.5 2.1 5% 75.5 42.0 2.0 7.5% 70.1 38.1 1.8 10% 65.5 35.5 1.7

5. Evaluation of antibacterial activity 1.

In addition, the antibacterial activity evaluation of the recycled PET fiber prepared as above was as follows.

Antibacterial activity was evaluated according to ASTM E2149-01, with Staphylococcus aureus (ATCC 6538) as a gram-positive bacteria and Klebsiella pneumoniae as a gram-negative bacteria. According to this measurement standard, an ASTM buffer solution must contain 34 g of potassium dihydrogen phosphate dissolved in 1000 mL of distilled water. Bacteria were cultured in buffer solution so that the final concentration was ^1.5 5 ml of bacterial culture was added to the flask, and PET fibers containing copper nanoparticles prepared according to Example 1, cut into small pieces, were added to each and then homogenized. A small amount of this solution was aliquoted and cultured in a Petri dish for 48 hours at 37°C for Gram-positive and Gram-negative bacteria, respectively. After the culture was completed, CFU was calculated and compared in each dish and listed in Table 2. When copper nanoparticles were included, a strong antibacterial effect was observed, and particularly strong activity against Gram-negative bacteria was observed. When more than 5% of copper nanoparticles are included, strong activity is observed, so it can be seen that it is preferable to include at least 5% of copper nanoparticles. Figure 11 shows the test results of PET fiber containing 5% copper nanoparticles and PET fiber without copper nanoparticles.

PET fiber
(copper nanoparticles %) Antibacterial activity
(Gram-positive bacteria) Antibacterial activity
(Gram-negative bacteria) 0% 0 % 0 % 0.05% 30% 50% One% 50% 75% 5% 85% 97% 7.5% 92% 99% 10% 99.8% 99.8%

6. Antibacterial activity evaluation 2.

Antibacterial activity was evaluated according to ASTM E2149-01, with Staphylococcus aureus (ATCC 6538) as a gram-positive bacteria and Klebsiella pneumoniae as a gram-negative bacteria. According to this measurement standard, an ASTM buffer solution must contain 34 g of potassium dihydrogen phosphate dissolved in 1000 mL of distilled water. Bacteria were cultured in buffer solution so that the final concentration was ^1.5 5 ml of bacterial culture was added to the flask, and PET fibers containing 5% of copper nanoparticles prepared according to Example 1, cut into small pieces, were added to each and then homogenized. Separately, PET fibers containing 5% copper nanoparticles prepared according to Example 2 were added to each and then homogenized. After homogenization, it was filtered through 0.45 micro membrane filter paper, and the PET fibers were again aliquoted and the redispersion process was repeated twice. A small amount of the final solution was aliquoted and cultured in a Petri dish for 48 hours at 37°C for Gram-positive and Gram-negative bacteria, respectively. After completion of incubation, CFU was calculated and compared in each dish and listed in Tables 3 and 4. The PET fiber containing 5% copper nanoparticles prepared according to Example 1 showed strong antibacterial activity even after being washed three times. On the other hand, it was confirmed that the antibacterial activity of the PET fiber using copper nanoparticles prepared through the process of Example 2 decreased rapidly after being washed three times. Therefore, it can be confirmed that when Dapamine is added as a stabilizer, antibacterial activity can be maintained even under conditions such as repeated washing.

Example 1 PET fiber using copper nanoparticles Antibacterial activity
(Gram-positive bacteria) Antibacterial activity
(Gram-negative bacteria) No washing 50% 97% 3 wash fabric 48% 95%

Example 2 PET fiber using copper nanoparticles Antibacterial activity
(Gram-positive bacteria) Antibacterial activity
(Gram-negative bacteria) No washing 52% 98% 3 wash fabric 35% 71%

In the above, the present invention has been described focusing on the embodiments described with reference to the attached drawings, but is of course not limited thereto. The following claims are intended to cover many modifications that may be naturally derived from these embodiments within the scope of the invention.

10: Backpack body 11: Opening and closing means
20: Shoulder 22: First fixing means
24: Second fixing means 30: Air injection and discharge type variable bulkhead
31: Elastic resin film 32: Fiber fabric
33: Sewing line 34: Air injection and discharge device (34)
B: Grid pattern 35: Third fixing means.
P: folding point 40: air pump
50: Control panel 60: Portable battery.

Claims (9)

The eco-friendly backpack consists of a backpack body (10), a shoulder rest (20), and an air injection and discharge type variable partition device (30) installed inside the backpack body, and the backpack body (10) is equipped with an opening and closing means (11) for opening and closing. is formed, and a first fixing device 22 is formed around the upper portion of the inner surface 21 of the backpack body 10, and the air injection and discharge type variable partition device 30 is detachable from the first fixing device. A first wall 31, a second wall 32, on which a second fixing device 31'1 is installed, and a plurality of variable partition walls 33 installed between the first and second walls. It consists of an air control device (35) installed at one end of the variable partition wall devices (30), an air distribution path (34) installed at the top of the first wall, and the air supply path (34). By connecting the regulating device 35, the variable partition walls 33 are fixed to the first wall, and the other ends of the two outermost variable partition devices among the variable partition devices are fixed to the second wall, thereby allowing the air distribution. By injecting air into the furnace 34 and the air control device 35, the variable partition wall 33 expands to widen the gap between the first wall and the second wall, thereby forming a storage space between the variable partition walls. The eco-friendly backpack is made of PET fiber made of PET composite containing copper nanoparticles and has antibacterial properties. According to paragraph 1,
The air injection and discharge type variable partition wall 33 has two elastic resin films 31'1 placed facing each other on the inside, and a fiber fabric 31' as an adhesive means on the outer surface of each elastic resin film 31'1. 2) is attached, sewn with fibers at predetermined intervals in the horizontal and vertical directions to form a seam line (31'3), and the entire outer peripheral surface is sealed with resin. According to paragraph 2,
An eco-friendly backpack, characterized in that a plurality of rod shapes (E) are formed by the seam line (31'3). According to paragraph 3,
An eco-friendly backpack, characterized in that the first and second fixing means are Velcro non-woven fabric. According to paragraph 3,
An eco-friendly backpack, characterized in that the variable partition walls can be selectively inflated by controlling air injection through an air control device (35) connected to each of the variable partition walls (33). According to paragraph 3,
An eco-friendly backpack, characterized in that the seam line (31'3) is formed by ultrasonic bonding the elastic resin film using an ultrasonic bonding means. According to paragraph 3,
An eco-friendly backpack, characterized in that the size of the rod shape expanded by air can be adjusted by adjusting the spacing between the seam lines (31'3). According to any one of claims 1 to 7,
The copper nanoparticles have a size distribution of less than 1 to 500 nm, are manufactured in a solution phase using both terephthalic acid and Dapamine as stabilizers, and are made into PET fibers using copper nanoparticles made into a dry phase through a freeze-drying process. An eco-friendly backpack characterized by manufacturing. According to clause 8,
An eco-friendly backpack, characterized in that the copper nanoparticles are mixed with PET fiber in a weight ratio of 0.01% to less than 7.5%.