JP7484480B2 - Bonding method and bonding system - Google Patents

Description

This disclosure relates to a bonding method and a bonding system.

Hot melt adhesives are solvent-free, so they place less strain on the environment and the human body, and because they can bond in a short time, they are suitable for improving productivity. Hot melt adhesives can be broadly divided into two types: those whose main component is a thermoplastic resin, and those whose main component is a reactive resin. The reactive resin mainly used is a urethane prepolymer with an isocyanate group at the end.

Hot melt adhesives are used in a variety of fields, including clothing (particularly seamless clothing that does not require sewing). For example, Patent Documents 1 and 2 disclose clothing in which pieces of fabric are bonded together with a hot melt adhesive.

JP 2017-186695 A JP 2010-203008 A

There are various types of fabrics that are adherends in the field of clothing, and the choice of which fabric to use is ultimately determined by the situation in which the clothing will be used. Therefore, it would be ideal to be able to apply one type of hot melt adhesive to bond fabrics together, but there are cases in which this is not possible. In order to apply hot melt adhesives to various types of fabrics, it is important to optimize the conditions for bonding (pressing) fabrics together via hot melt adhesive for each type of fabric. In general, the conditions for bonding (pressing) fabrics together include temperature, load (pressure), time, etc., which are considered to be influential factors. However, due to the large number of influential factors, optimizing the bonding conditions (pressing conditions) requires a lot of effort, and when multiple hot melt adhesives are used, this effort increases even more. Therefore, when bonding fabrics together via hot melt adhesives, there is a demand for a bonding method that can easily optimize the bonding conditions to obtain an adhesive body in which the fabrics are firmly bonded together.

Therefore, the main objective of this disclosure is to provide a lamination method for laminating fabrics together using a hot melt adhesive that allows for easy optimization of lamination conditions.

The inventors' investigations have revealed that the most important influencing factor when bonding fabrics together with hot melt adhesive is temperature (compression temperature). After further investigation, the inventors have discovered that there is a correlation between the density of the fabric and the adhesive strength of the hot melt adhesive, and that this correlation can be used to derive the optimal temperature (compression temperature) that provides high adhesive strength for multiple hot melt adhesives when bonding fabrics together with hot melt adhesive from the density of the fabric, leading to the completion of the disclosed invention.

One aspect of the present disclosure relates to a bonding method for bonding fabrics (hereinafter, sometimes referred to as "target fabrics") together via a hot melt adhesive (hereinafter, sometimes referred to as "target hot melt adhesive"). The bonding method includes a first step of determining the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric based on a correlation (hereinafter, sometimes referred to as "first correlation") between the density of the standard fabric and the viscosity of the standard hot melt adhesive that provides the maximum adhesive strength at the density, which is obtained in advance using a standard hot melt adhesive that may be the same as or different from the target hot melt adhesive and a plurality of standard fabrics that may include the target fabric; a second step of determining the temperature at which the viscosity of the target hot melt adhesive becomes the viscosity determined in the first step based on a correlation (hereinafter, sometimes referred to as "second correlation") between the temperature of the target hot melt adhesive and the viscosity at that temperature; and a third step of bonding the target fabrics together via the target hot melt adhesive at the temperature determined in the second step. Here, the target hot melt adhesive and the target fabric are the hot melt adhesive and fabric used when bonding the fabrics together. Meanwhile, the standard hot melt adhesive and the standard fabric are the hot melt adhesive and fabric used to determine the first correlation in the first step. According to this bonding method, when bonding the target fabrics together using the target hot melt adhesive, the bonding conditions, particularly the temperature (pressing temperature) conditions which are considered to be the most important influencing factor, can be easily optimized, and an adhesive body in which the target fabrics are firmly bonded together can be obtained.

Another aspect of the present disclosure relates to a lamination system. The lamination system includes a lamination unit that bonds target fabrics together via a target hot melt adhesive, a calculation unit that determines the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric based on a first correlation that is obtained in advance using a standard hot melt adhesive that may be the same as or different from the target hot melt adhesive and a plurality of standard fabrics that may include the target fabric, and that determines the temperature at which the viscosity of the target hot melt adhesive becomes the determined viscosity based on a second correlation, and a control unit that controls the temperature of the target hot melt adhesive in the lamination unit based on the temperature determined by the calculation unit.

According to the present disclosure, a lamination method is provided in which fabrics are bonded together using a hot melt adhesive, and the lamination conditions can be easily optimized. With this lamination method, it is possible to obtain an adhesive body in which the fabrics are firmly bonded together. Furthermore, according to the present disclosure, a lamination system capable of carrying out this lamination method is provided.

FIG. 1 is a logarithmic graph showing the correlation between temperature and viscosity at that temperature for a standard hot melt adhesive. FIG. 2 is a logarithmic graph showing the correlation (first correlation) between the density of a standard substrate and the viscosity of a standard hot melt adhesive that provides maximum adhesive strength at that density. FIG. 3 is a logarithmic graph showing (a second correlation) between the temperature of a hot melt adhesive (a target hot melt adhesive) and the viscosity at that temperature. FIG. 4 is a schematic diagram showing an embodiment of a lamination system.

Embodiments of the present disclosure are described below. However, the present disclosure is not limited to the following embodiments.

[Lamination method]
The lamination method of one embodiment includes at least a first step, a second step, and a third step. According to such a lamination method, when laminating fabrics with a hot melt adhesive, it is possible to easily optimize lamination conditions, particularly temperature (compression temperature) conditions, which are considered to be the most important influencing factor.

(Hot melt adhesive)
The target hot melt adhesive is the hot melt adhesive used in performing the lamination, and the standard hot melt adhesive is the hot melt adhesive used to determine the first correlation in the first step.

The target hot melt adhesive and the standard hot melt adhesive may be a moisture-curing hot melt adhesive containing a urethane prepolymer. In general, a moisture-curing hot melt adhesive is one that is polymerized by a chemical reaction and can exhibit adhesive strength, etc. Here, since a urethane prepolymer having an isocyanate group reacts with moisture to cure (to form a cured product), the moisture-curing hot melt adhesive may be made of urethane prepolymer alone, or may contain, in addition to the urethane prepolymer, additives used in the field of moisture-curing hot melt adhesives, etc.

The urethane prepolymer may be a reaction product of a polyol and a polyisocyanate. The urethane prepolymer may be, for example, a urethane prepolymer having an isocyanate group. A urethane prepolymer having an isocyanate group usually has a polymer chain containing a structural unit derived from a polyol (a compound having two or more hydroxyl groups in the molecule) and a structural unit derived from a polyisocyanate (a compound having two or more isocyanate groups in the molecule), and an isocyanate group. The isocyanate group may be bonded to the end of the polymer chain. The composition of the urethane prepolymer can be changed by changing the type and content of the polyol that provides the structural unit derived from the polyol and the type and content of the polyisocyanate that provides the structural unit derived from the polyisocyanate. In addition, since a urethane bond is formed by the reaction of the polyol and the polyisocyanate, the polymer chain of the urethane prepolymer has a urethane bond. In addition, an isocyanate group can be introduced to the end of the polymer chain by increasing the ratio of the equivalent of the polyisocyanate to the equivalent of the polyol.

The standard hot melt adhesive may be the same as or different from the target hot melt adhesive, but is usually different from the target hot melt adhesive. When the standard hot melt adhesive is different from the target hot melt adhesive, this includes, for example, when the urethane prepolymer compositions are different, or when the urethane prepolymer compositions are the same but the types and amounts of additives are different.

The target hot melt adhesive and the standard hot melt adhesive preferably have in common that they are included in a viscosity range that is arbitrarily set at an arbitrary temperature. Here, the arbitrary temperature may be, for example, 120°C and/or 30°C. The viscosity range that is arbitrarily set at 120°C may be, for example, 0.01 Pa·s or more, 0.05 Pa·s or more, or 0.1 Pa·s or more, and may be 30 Pa·s or less, 20 Pa·s or less, or 15 Pa·s or less. The viscosity range that is arbitrarily set at 30°C may be, for example, 100 Pa·s or more, 1000 Pa·s or more, or 10000 Pa·s or more, and may be 1000000 Pa·s or less, 500000 Pa·s or less, or 100000 Pa·s or less. When the target hot melt adhesive and the standard hot melt adhesive have this kind of relationship, the bonding conditions can be more easily optimized, resulting in an adhesive in which the fabrics are more firmly bonded together.

The viscosity of the target hot melt adhesive at 120°C and the viscosity of the standard hot melt adhesive at 120°C may be 0.01 Pa·s or more, 0.05 Pa·s or more, or 0.1 Pa·s or more, and may be 30 Pa·s or less, 20 Pa·s or less, or 15 Pa·s or less. Having a viscosity at 120°C within the above range improves workability (handling) when applying the moisture-curing hot melt adhesive to an adherend with a dispenser or the like.

The viscosity of the target hot melt adhesive at 30°C and the viscosity of the standard hot melt adhesive at 30°C may be 100 Pa·s or more, 1000 Pa·s or more, or 10,000 Pa·s or more, and may be 1,000,000 Pa·s or less, 500,000 Pa·s or less, or 100,000 Pa·s or less. When the viscosity at 30°C is within the above range, the adhesive strength immediately after pressing is high, and the adhesive product becomes easy to handle.

(material)
The target fabric means a fabric used when performing pasting, and the standard fabric means a fabric used to obtain the first correlation in the first step. A plurality of standard fabrics are prepared, and in this case, the standard fabric may include the target fabric. Here, the standard fabric includes the target fabric means that the standard fabric includes a fabric with the same density as the target fabric. The pasting of the fabrics may be a pasting of a pair (two sheets) of fabrics that are separated, or may be a pasting of fabrics within a single piece of fabric that is not separated. In pasting a pair (two sheets) of fabrics that are separated (target fabrics (combination of target fabrics) and standard fabrics (combination of standard fabrics)), the prepared fabrics may be a combination of fabrics with the same density as each other, or a combination of fabrics with different densities from each other. It is preferable that the prepared fabrics are a combination of fabrics with the same density as each other. In pasting of fabrics within a single piece of fabric that is not separated, the combination of fabrics is usually the same density as each other, but it may also be a combination of fabrics with different densities from each other. The density of the material may be, for example, 0.1 to 1.0 g/cm ³ from the viewpoint of adhesiveness.

(First step)
In this process, the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric is determined based on a first correlation that has been previously obtained using a standard hot melt adhesive, which may be the same or different from the target hot melt adhesive, and a number of standard fabrics, which may include the target fabric.

The standard hot melt adhesive may be the same as or different from the target hot melt adhesive, but is usually different from the target hot melt adhesive. Therefore, the first step may include a step (a) of obtaining a first correlation using a standard hot melt adhesive different from the target hot melt adhesive and a plurality of standard fabrics that may include the target fabric, and a step (b) of determining the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric based on the first correlation obtained in the step (a).

The first correlation in step 1 (a) can be obtained, for example, by the following procedure. First, the adhesive strength under each bonding condition (pressing condition) is obtained by varying the parameters of temperature, load, and time for standard fabrics using a standard hot melt adhesive. The adhesive strength can be actually measured. When determining the adhesive strength, it is preferable that the standard fabrics are a combination of fabrics having the same density. The actual measurement conditions for the adhesive strength include, for example, the method described in the Examples. When actually measuring the adhesive strength, it is preferable to perform the measurement based on an experimental plan created using commercially available statistical analysis software, since the parameters of the bonding conditions (pressing conditions) can be varied widely and efficiently.

Next, using commercially available statistical analysis software (for example, statistical analysis software "JMP" (manufactured by SAS) etc.), the adhesive forces (calculated values) are calculated based on the measured adhesive forces when the parameters of temperature, load, and time are varied, and the adhesive force that is the maximum among the calculated adhesive forces (i.e., the maximum adhesive force for the density of the standard fabric) is determined. For example, when two fabrics with the same density are combined, the maximum adhesive force for the density of the standard fabric must be determined for each combination of different densities. After that, for each maximum adhesive force for the density of multiple standard fabrics, the temperature, load, and time that give the maximum adhesive force are determined.

Next, the temperature that gives the maximum adhesive strength for the density of the standard fabric is determined based on the correlation between the temperature of the standard hot melt adhesive and the viscosity at that temperature (see, for example, Figure 1). Here, the correlation between the temperature of the standard hot melt adhesive and the viscosity at that temperature is a correlation that is usually measured in the field of hot melt adhesives.

By these procedures, a first correlation can be obtained, which is a correlation between the density of the standard fabric and the viscosity of the standard hot melt adhesive that provides the maximum adhesive strength at that density (see, for example, Figure 2). The first correlation serves as a calibration curve, so to speak, and is obtained in advance when determining the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric in the first step.

Step 1(b) is a step of determining the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric based on the first correlation obtained in step 1(a). The target hot melt adhesive and the target fabric are the hot melt adhesive and fabric used when bonding. Here, by introducing the numerical value of the density of the target fabric used when bonding into the first correlation (see FIG. 2), the viscosity of the target hot melt adhesive that provides the maximum adhesive strength can be determined. The target hot melt adhesive may be used to bond a pair (two sheets) of target fabrics that are separated, or may be used to bond target fabrics within a single sheet of target fabric that is not separated.

In bonding a pair (two sheets) of separated target fabrics, the pair (two sheets) of target fabrics may be a combination of fabrics with the same density or a combination of fabrics with different densities. It is preferable that the pair (two sheets) of target fabrics are a combination of fabrics with the same density. When the pair (two sheets) of target fabrics are a combination of fabrics with the same density, the density can be introduced into the first correlation to determine the viscosity of the target hot melt adhesive that provides the maximum adhesive strength. When the pair (two sheets) of target fabrics are a combination of fabrics with different densities, the target fabric on the higher density side of the pair (two sheets) of target fabrics tends to be insufficient in terms of maximum adhesive strength, so it is preferable to introduce the density of the target fabric on the higher density side into the first correlation to determine the viscosity of the target hot melt adhesive that provides the maximum adhesive strength.

On the other hand, when bonding fabrics together within a single piece of fabric that is not separated, the fabrics are usually combined with the same density, but may be combined with fabrics of different densities. When the fabrics are combined with the same density, the density can be introduced into the first correlation to determine the viscosity of the target hot melt adhesive that provides the maximum adhesive strength. When the fabrics are combined with different densities, it is preferable to introduce the density of the higher density side into the first correlation to determine the viscosity of the target hot melt adhesive that provides the maximum adhesive strength.

(Second step)
In this step, the temperature at which the viscosity of the target hot melt adhesive becomes the viscosity determined in the first step is determined based on the second correlation. The second correlation (see FIG. 3) is a correlation that is usually measured in the field of hot melt adhesives, similar to the correlation between the temperature of the standard hot melt adhesive and the viscosity at that temperature (see FIG. 1). By introducing the value of the viscosity determined in the first step (the viscosity of the target hot melt adhesive that gives the maximum adhesive strength) into the second correlation (see FIG. 3), the temperature at which the viscosity of the target hot melt adhesive becomes the viscosity determined in the first step can be determined.

(Third step)
In this step, the target fabrics are bonded together via the target hot melt adhesive at the temperature determined in the second step. The temperature determined in the second step is the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric, so it is possible to obtain an adhesive body in which the target fabrics are firmly bonded together.

[Lamination system]
Fig. 4 is a schematic diagram showing one embodiment of a bonding system. The bonding system 10 shown in Fig. 4 includes at least a bonding unit 2, a calculation unit 4, and a control unit 6. According to such a bonding system 10, it is possible to carry out the bonding method of bonding fabrics together via the above-mentioned hot melt adhesive.

The lamination unit 2 is for laminating the target fabrics together via the target hot melt adhesive. The hot melt adhesive is usually heated to melt it, and then applied to the desired area before use. For this reason, the lamination unit 2 may have, for example, a melting means such as a heating mixer for melting the target hot melt adhesive, an application means such as a dispenser, a bar coater, a die coater, a roll coater, or a spray for applying the molten target hot melt adhesive, a pressing means such as a press machine for laminating the target fabrics together via the applied target hot melt adhesive, a heating means such as a heater for heating the temperature when laminating the target fabrics together, and a temperature measuring means such as a thermocouple for measuring the temperature of the heating means when laminating the target fabrics together.

The calculation unit 4 is for determining the viscosity of the target hot melt adhesive that provides the maximum adhesive strength at the density of the target fabric based on a first correlation obtained in advance using a standard hot melt adhesive that may be the same as or different from the target hot melt adhesive and a plurality of standard fabrics that may include the target fabric, and for determining the temperature at which the viscosity of the target hot melt adhesive becomes the determined viscosity based on the second correlation. The calculation unit 4 may have, for example, a first input means for inputting the first correlation obtained in advance, a second input means for inputting the second correlation, a third input means for inputting the density of the target fabric, etc. Instead of the second input means, the calculation unit 4 may have a first measurement means for actually introducing the target hot melt adhesive and measuring the second correlation based on the introduced target hot melt adhesive, and instead of the third input means, a second measurement means for actually introducing the target fabric and measuring its density based on the introduced target fabric.

The control unit 6 is for controlling the lamination temperature in the lamination unit 2 based on the temperature determined by the calculation unit 4. The control unit 6 may have, for example, an acquisition means for acquiring information about the temperature determined by the calculation unit 4, a receiving means for receiving information about the temperature of the heating means measured from the temperature measuring means of the lamination unit 2, and an output means for outputting a signal corresponding to the temperature determined by the calculation unit 4 from the control unit 6 to the heating means based on a signal corresponding to the temperature of the heating means received by the receiving means.

The elements of the lamination unit, the calculation unit, and the control unit may be electrically connected, for example, by wire or wirelessly.

The present disclosure will be described in detail below with reference to examples, but the present disclosure is not limited to these.

[Preparing standard fabric]
The following dough was prepared:
Fabric A (density: 0.25 g/cm ³ )
Fabric B (density: 0.25 g/cm ³ )
Fabric C (density: 0.34 g/cm ³ )
Fabric D (density: 0.45 g/cm ³ )
Fabric E (density: 0.45 g/cm ³ )
Fabric F (density: 0.57 g/cm ³ )

Preparation of standard hot melt adhesives
80 parts by mass of an amorphous polyester polyol having an aromatic ring (number of hydroxyl groups: 2, number average molecular weight: 2000) mainly composed of dicarboxylic acid (adipic acid and isophthalic acid) and diol (ethylene glycol and neopentyl glycol), 4 parts by mass of an amorphous polyether polyol having an aromatic ring (manufactured by ADEKA Corporation, product name: BPX-11), and 16 parts by mass of an amorphous polyester polyol not having an aromatic ring (number of hydroxyl groups: 2, number average molecular weight: 2000) mainly composed of dicarboxylic acid (adipic acid) and diol (neopentyl glycol and propylene glycol) were previously dehydrated using a vacuum dryer. Diphenylmethane diisocyanate (manufactured by Tosoh Corporation, trade name: Millionate MT, number of isocyanate groups: 2) was added to the reaction vessel so that the equivalent ratio ((NCO) equivalent/(OH) equivalent) of the isocyanate group of the polyisocyanate to the hydroxyl group of the polyol was 1.8, and mixed at 110°C for 1 hour until uniform. Next, a urethane prepolymer was obtained by further degassing and stirring at 110°C for 1 hour. In the following, the obtained urethane prepolymer was used as it is as a standard hot melt adhesive. FIG. 1 is a logarithmic graph showing the correlation between the temperature of the standard hot melt adhesive and the viscosity at that temperature. The graph is a graph in which the viscosity is plotted for each predetermined temperature (for example, 1°C) in the standard hot melt adhesive. The viscosity of the standard hot melt adhesive at 120°C was 12 Pa·s.

[Calculation of maximum adhesive strength of standard hot melt adhesive for standard fabric density]
(Preparation of Laminate)
Using the standard hot melt adhesive and the standard substrate (substrate A), the maximum adhesive strength of the standard hot melt adhesive relative to the substrate density was calculated. The prepared standard hot melt adhesive was melted at 110°C and applied to substrate A using a dispenser to form a linear adhesive layer. Another standard substrate (substrate A) was placed on the linear adhesive layer formed to obtain a laminate. A plurality of laminates (16 pieces) were prepared in accordance with the production of the pressure-bonded body described below.

(Preparation of pressure-bonded body)
The temperature (bonding temperature) (lower limit: 30°C, upper limit: 60°C), load (bonding load) (lower limit: 40N, upper limit: 120N), and time (bonding time) (lower limit: 1 second, upper limit: 9 seconds) were set as parameters of the bonding conditions, and an experimental plan was created using the statistical analysis software "JMP". The number of experiments in the experimental plan was 16. A bonded body was obtained by bonding the laminate based on the predetermined bonding conditions of the experimental plan.

(Preparation of Adhesive and Measurement of Adhesive Strength)
The bonded bodies for each experimental plan were aged in a thermostatic chamber at 23°C and 50% RH for one day to cure the adhesive layer, thereby obtaining each bonded body. The adhesive strength (actual value) of each bonded body was determined by a T-peel strength test using a tensile tester (Shimadzu Corporation, EZ-Test EZ-SX) at a measurement temperature of 25°C and a tensile speed of 100 mm/min.

(Calculation of maximum adhesive strength of standard hot melt adhesive for standard fabric density)
Using the statistical analysis software "JMP" (manufactured by SAS), the adhesive strength (calculated value) when the parameters of temperature, load, and time were varied was calculated based on the data of the adhesive strength (actual value) of the above-mentioned adhesive body under the conditions of a given temperature, load, and time, and the adhesive strength (calculated value) that was the maximum among the adhesive strengths (calculated values) was determined as the maximum adhesive strength of the standard hot melt adhesive for the density of the standard fabric. More specific operations in "JMP" are as follows. First, the adhesive strength (actual value) of each adhesive body was input on "JMP", and "model fitting" was performed using "standard least squares" approximation in the obtained data table to obtain a "prediction profile". Next, "maximize and record" was performed with the default setting, and the setting that maximizes "satisfaction" was displayed to obtain the maximum adhesive strength. Table 1 shows the maximum adhesive strength of the standard hot melt adhesive for the density of the standard fabric, as well as the temperature, load, and time that give the maximum adhesive strength. In addition, based on the graph showing the correlation between the temperature of the standard hot melt adhesive and the viscosity at that temperature shown in FIG. 1, the viscosity that gives the maximum adhesive strength was calculated from the temperature that gives the maximum adhesive strength. The results are shown in Table 1.

(Change of standard fabric)
The combination of fabrics was changed from Fabric A x Fabric B x Fabric C x Fabric D x Fabric E x Fabric F x Fabric F x Fabric F, and the maximum adhesive strength of the standard hot melt adhesive for the density of the standard fabric was determined in the same manner as above, as well as the temperature, load, time, and viscosity that gave the maximum adhesive strength. The results are shown in Table 1.

(Calculation of maximum adhesive strength of standard hot melt adhesive for standard fabric density)
Fig. 2 is a logarithmic graph showing a correlation (first correlation) between the density of a standard fabric and the viscosity of a standard hot melt adhesive that provides the maximum adhesive strength at that density. The curve in Fig. 2 is a power-approximated curve, and in the following, this graph (curve) is used to determine the viscosity of a hot melt adhesive (target hot melt adhesive) that provides the maximum adhesive strength at the density of a fabric (target fabric).

[Preparation of target hot melt adhesive]
50 parts by mass of an amorphous polyester polyol (hydroxyl group number: 2, number average molecular weight: 2000) having an aromatic ring, mainly composed of dicarboxylic acid (adipic acid and isophthalic acid) and diol (ethylene glycol and neopentyl glycol), and 50 parts by mass of an amorphous polycarbonate polyol (manufactured by Asahi Kasei Corporation, product name: DURANOL T5652) were dehydrated in advance by a vacuum dryer. Diphenylmethane diisocyanate (manufactured by Tosoh Corporation, product name: Millionate MT, number of isocyanate groups: 2) was added to a reaction vessel so that the equivalent ratio ((NCO) equivalent/(OH) equivalent) of the isocyanate group of the polyisocyanate to the hydroxy group of the polyol was 2.0, and mixed at 110 ° C. for 1 hour until uniform. Next, a urethane prepolymer was obtained by further degassing and stirring under reduced pressure at 110 ° C. for 1 hour. In the following, the obtained urethane prepolymer was used as it is as a target hot melt adhesive. The viscosity of the target hot melt adhesive at 120°C was 8 Pa·s.

[Determination of temperature when pressing target fabrics together with target hot melt adhesive]
FIG. 3 is a graph showing the correlation (second correlation) between the temperature of the hot melt adhesive (target hot melt adhesive) and the viscosity at that temperature. The graph is a graph in which the viscosity of the target hot melt adhesive is plotted for each predetermined temperature (for example, 1°C). The viscosity of the hot melt adhesive (target hot melt adhesive) that gives the maximum adhesive strength at the density of the fabric (target fabric) obtained above was introduced into the second correlation to determine the temperature at that time. When the density of the target fabric was 0.49 g/ ^cm3 , the optimal viscosity and optimal temperature of the target hot melt adhesive when pressing the target fabrics together were 3063 Pa·s and 41°C, respectively. When the density of the target fabric was 0.62 g/ ^cm3 , the optimal viscosity and optimal temperature of the target hot melt adhesive when pressing the target fabrics together were 497 Pa·s and 52°C, respectively.

[Lamination study under specified pressure bonding conditions]
(Examples 1-1 to 1-5)
A pair (two sheets) of target fabrics with a density of 0.49 g/ ^cm3 were prepared. The target hot melt adhesive obtained above was melted at 110°C and applied to one target fabric with a dispenser. An 18G needle was used for application to form an adhesive layer with a length of 8 cm. Next, another target fabric was placed on the formed adhesive layer, and the temperature conditions were unified to 41°C, and the two were pressed under the load (pressure) conditions and time conditions shown in Table 2 to obtain a pressed body. When the adhesive strength of the pressed body was measured 5 minutes after the pressing, it had sufficient adhesive strength in Examples 1-1 to 1-5.

(Examples 2-1 to 2-5)
A pair (two sheets) of target fabrics with a density of 0.62 g/ ^cm3 were prepared. The target hot melt adhesive obtained above was melted at 110°C and applied to one target fabric with a dispenser. An 18G needle was used for application to form an adhesive layer with a length of 8 cm. Next, another target fabric was placed on the formed adhesive layer, and the temperature conditions were unified to 52°C, and the two were pressed under the load (pressure) conditions and time conditions shown in Table 3 to obtain a pressed body. When the adhesive strength of the pressed body was measured 5 minutes after the pressing, it had sufficient adhesive strength in Examples 2-1 to 2-5.

From the above, it has been confirmed that the bonding method disclosed herein makes it possible to easily optimize bonding conditions in a bonding method in which fabrics are bonded together using a hot melt adhesive.

2...Laminating unit, 4...Calculation unit, 6...Control unit, 10...Laminating system.

Claims (2)

A bonding method for bonding fabrics together using a hot melt adhesive, comprising the steps of:
A first step of determining the viscosity of the hot melt adhesive that gives the maximum adhesive strength at the density of the material based on a first correlation between the density of the standard material and the viscosity of the standard hot melt adhesive that gives the maximum adhesive strength at the density, the first correlation being obtained in advance using a standard hot melt adhesive that may be the same or different as the hot melt adhesive and a plurality of standard materials that may include the material;
A second step of determining a temperature at which the viscosity of the hot melt adhesive becomes the viscosity determined in the first step based on a second correlation between the temperature of the hot melt adhesive and the viscosity at the temperature;
A third step of bonding the fabrics together via the hot melt adhesive at the temperature determined in the second step;
Equipped with
When the fabrics are a combination of fabrics having the same density, the first step is a step of introducing the densities of the fabrics into the first correlation to determine the viscosity of the hot melt adhesive that gives the maximum adhesive strength,
When the fabrics are a combination of fabrics having different densities, the first step is a step of introducing the density of the fabric having a higher density into the first correlation to determine the viscosity of the hot melt adhesive that provides the maximum adhesive strength. A bonding system for carrying out the bonding method according to claim 1,
a bonding section that bonds the fabrics together using a hot melt adhesive;
a calculation unit which determines the viscosity of the hot melt adhesive which gives the maximum adhesive strength at the density of the fabric based on the first correlation between the density of the standard fabric and the viscosity of the standard hot melt adhesive which gives the maximum adhesive strength at the density, the first correlation being obtained in advance using a standard hot melt adhesive which may be the same as or different from the hot melt adhesive, and a plurality of standard fabrics which may include the fabric, and which determines the temperature at which the viscosity of the hot melt adhesive becomes the determined viscosity based on the second correlation between the temperature of the hot melt adhesive and the viscosity at that temperature;
A control unit that controls the temperature of the hot melt adhesive in the bonding unit based on the temperature determined by the calculation unit;
A lamination system comprising:

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