TH8131B

TH8131B - Solvent-free functional coating

Info

Publication number: TH8131B
Application number: TH9201001460A
Authority: TH
Inventors: เกรกอรี่ไอแอน ฟอสเตอร์ นาย; เควินฮิลตัน กรีน นาย; แกรรีย์ไมเคิล แม็คเคย์ นาย; โรเจอร์โอเวน เอ็ดเวิร์ดส์ นาย
Original assignee: นางสาว จุฑาจิตศรีประสาธน์; นาย ชวลิตอัตถศาสตร์; นาย ชวลิตอัตถศาสตร์ นาย รัชพงษ์ทองดีแท้ นางสาว จุฑาจิตศรีประสาธน์; นาย รัชพงษ์ทองดีแท้
Filing date: 1992-10-14
Publication date: 1998-06-22

Abstract

การประดิษฐ์นี้เปิดเผยถึงส่วนประกอบที่ปราศจากจากตัวทำละลายที่เหมาะสม ที่จะใช้เป็นสารหลอมร้อน ที่ซับสเทรต ส่วนประกอบดังกล่าวประกอบด้วยสารผสม หรือ อัลลอยด์ของเรซิน ที่ถูกเลือกเพื่อว่า ให้ค่าอุณหภูมิสภาพแก้ว (Tg) โดยเฉลี่ยของเรซิน ที่ไม่ทำปฏิกิริยา ที่รวมอยู่นั้นมากกว่า -30 ํ และน้อยกว่า -60 ํซ ความหนืดสารหลอม ของเรซินที่ไม่ทำปฏิกิริยาได้ถูกเลือกเพื่อว่า สารผสมเรซินที่รวมกันนั้นมีความหนืดสารหลอม จากประมาณ 0.05 ถึง 25 พอยส์ เมื่อวัดที่ 180 ํซ และที่อัตราเฉือน 10,000 Hz The invention revealed suitable solvent-free components. To be used as a hot melt substrate, the component contains a mixture of resin or alloy. That were chosen so that Gives the average glass temperature (Tg) of the resin. Non-reactive The total viscosity is greater than -30 ํ and less than -60 ํ melt viscosity. Of the inactive resin was selected so The combined resin mixture had a molten viscosity of approximately 0.05 to 25 points when measured at 180 ํ and at a shear rate of 10,000 Hz.

Claims

1. A thermosetting component suitable to be used as a hot melt to a substrate. The component consists of various resin mixtures or alloys that are selected in order to: The average glass temperature (Tg) of the unreactive resin was greater than -30 ํ and less than +60 ํ, and where the combined resin mix was viscosity. From approx. 0.05 to 25 pts when measured at 180 ํ and at a shear rate of 10,000 Hz.

2. Composition according to claim 1, where at least one of the resins has pigment dispersed in it.

3. Composition according to claim 1 or claim 2, where the different resins are selected so that at least one resin has a temperature greater than +20 ํ and the other. The glass temperature is less than +20 ํ.

4. Composition according to claim 3 where one of the different resins has Tg greater than +30 ํ and less than 110 ํ and the other has Tg less than 5 ํ and more than -100 ํ.

5. Composition according to claim 4 where one of the different resins has Tg greater than 30 ํ and less than 70 ํ and the other has Tg less than 5 ํ and more than -60 ํ.

6. Any component of any of the aforementioned Claims where The combined non-reactive resins have an average Tg of -10 ํ to +40 ํ.

7. Any component of the aforementioned Claim where The viscosity of the various resins were selected so that the combined resin mixtures had a fused viscosity from 0.1 to 12 pts when measured at 180 ํ and at a shear rate of 10,000 Hz (or equal).

8. Any component according to the claim of Clause 2 that the pigment is dispersed. In the resin composition with Tg above 20 ํ and the viscosity above 6 pt at 180 ํ.

9. Composition according to one of the above claims, where the various resins are selected from the polyester-containing group. Polyester treated by silicone, acrylic, alkyd, epoxy, melanine-formaldehyde. Urea-formaldehyde Phenol - formaldehyde Polymers with fluorine Chlorinated polymers, urethane resins and elastomers 1

0. Composition according to claim 9 where at least one of the resin is polyester resin 1.

1. One of the components that is mostly described here referring to example 2 or 4 or 5.

2. A production method without thermosetting solvent consisting of a procedure of (1) selection of the first resin with a glass state temperature (Tg) above +20 ํ (2). Select a second resin with Tg less than +20 ํ (3) dispersing pigment into the first resin, and (4) combining the first resin with the second resin in proportion to the Tg of resin. The non-reactive mixture that was incorporated was greater than -30 ํ and less than +60 ํ and where the combined resin mixture had a fused viscosity of approximately 0.05 to 25 point when measured. At 180 ํ and at a shear rate of 10,000 Hz 1

3. Method according to claim 12 that the dispersion stage is performed in Extruder 1

4. Method according to claim 13 where the extruder is a multi-way extruder and where the first resin is put first. And silica is inserted into the resin at the second stream. Down from the first pass 1

5. Method for any one of Clause 12 through 14, where the silica is to be incorporated into the second resin. Before, there was a combination of the second resin with the first resin 1.

6. Method for any of the claims 12 to 15, where the first resin has Tg more than 30 ํ and less than 110 ํ 1.

7. Method according to one of the claims 12 through 16, where the first resin has a molten viscosity greater than 6 points at 180 ํ C 1.

8. Clause 12 to Section 17 of the Clause 17 where Tg is below 5 ํ and over -60 ํ C 1.

9. Any of the Clause 12 to 18 Clause 18, where the first resin is picked out of the group containing the treated polyester. Modified with silicone, acrylic, alkyd, epoxy, melanine-formaldehyde, urea, formaldehyde. Phenol-formaldehyde, chlorinated polymers Chlorinated polymers, urethane resins and elastomers 2

0. Any of the Clause 12 to 19 Clause 19, where the second resin is independently selected from the polyester-containing group. Polyester treated with silicone, acrylic, alkyd, epoxy, melanine-formaldehyde. Urea-formaldehyde, phenol-formaldehyde Polymers with fluorine Chlorinated polymers, urethane resins, and elasms