DOI: 10.17344/acsi.2015.1924 Acta Chim. Slov. 2016, 63, 77-87 77 Scientific paper Melamine Polyphosphate - the Reactive and Additive Flame Retardant for Polyurethane Foams Jacek Lubczak and Renata Lubczak Faculty of Chemistry, University of Technology, Al. Powstanicow Warszawy 6, 35-959 Rzeszow, Poland * Corresponding author: E-mail: jml@prz.edu.pl Received: 20-08-2015 Abstract Melamine polyphosphate (MPP) was applied as reactive and additive flame retardant for thermally resistant polyurethane foams. MPP was hydroxyalkylated with ethylene and propylene carbonates to get oligoetherols with 1,3,5-triazine ring and phosphorus. The structure and physical properties of the products were studied. The polyurethane foams, (PUFs) obtained from this oligoetherols were self-extinguishing. The addition of powdered MPP into foaming mixture resulted in further decrease of flammability modified PUFs. The MPP-modified PUFs were characterized by physical methods adequate to thermal resistance and flammability of the PUFs. The best MPP-modified PUF showed oxygen index 24.6. All the modified PUFs were remarkably thermally resistant; they could stand long lasting thermal exposure even at 200 °C. Keywords: Melamine polyphosphate, oligoetherols, polyurethane foams, properties, thermal stability, flammability. 1. Introduction Oligoetherols with incorporated 1,3,5-triazine ring (II) can be obtained from melamine (I) and excess alkyle-ne carbonates, like ethylene (EC) or propylene (PC) carbonates:1'2 Thermally resistant polyurethane foams (trPUFs) from these polyetherols, water and isocyanates have been obtained.3 Classic PUFs undergo decomposition at temperatures above 90 °C,4,5 while trPUFs with 1,3,5-triazine rings are resistant against long lasting heating even at 200 °C.6 This renders them useful materials as thermal isolators. On the other hand they are flammable, therefore we have undertaken systematic study to decrease the flamma-bility of PUFs based on 1,3,5-triazine ring in order to improve their properties as potential thermoinsulators. Flame retardation of polyurethanes can be achieved by incorporation elements like chlorine, bromine, phosphorus, nitrogen or silicon into polyurethane or into the oli-goetherol substrate.7,8 By introduction of flame retardants, where: x + y + z + p + q + m = n R = -H, -CH3 Scheme 1. Synthesis of oligoetherols from melamine and alkylene carbonate. Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... 78 Acta Chim. Slov. 2016, 63, 77-87 87 Scheme 2. Obtaining of MPP. in other word antipyrenes, the pyrolysis of polymeric materials as well as flame resistant can be considerably restricted and finally self-extinguishing materials can be obtained. Antipyrenes can be divided into two groups.9 namely: (i) reactive retardants, which are incorporated into chemical structure of polymers at the stage of polymer synthesis or cross-linking, and (ii) additive flame retardants, which are incorporated into polymer as non-reacting compounds to form compositions. Introducing phosphorus and nitrogen into polyurethane foams effectively increases the PUFs flame resistance. Especially the simultaneous modification of PUFs with nitrogen and phosphorus is desirable due to synergy between those two elements.10-12 Thus, the best known flame retardants are ammonium phosphates and melamine and MPP.13 Addition of flame retardants decreases the percentage of flammable parts of composites. Moreover, upon decomposition at 350 °C the MPP degrades endot-hermally, and released phosphoric acid deposits on the surface and forms the film, which is the thermal barrier for hest transfer into polymer.14 MPP can be obtained by thermal conversion of melamine phosphate into melami-ne pyrophosphate at 250-300 °C and further into MPP at 300-330 °C.13 We have described here the results of our attempts on MPP as reactive and additive retardant for PUFs of enhanced thermal stability and increased flammability. 2. Experimental Section 2. 1. Synthesis of Oligoetherols from MPP and Alkylene Carbonates MPP (16.5 g, 0.08 mole of mers, pure, Zaklady Che-miczne „Alwernia", Poland), EC (154.9 g, 1.76 mole or 70.4 g, 0.8 mole, pure, Fluka, Buchs, Switzerland) and potassium carbonate as catalyst (1.6 g and 0.8 g, respectively) were placed in three-necked 250 cm3 flask equipped with mechanical stirrer, thermometer and reflux condenser. The mixture was heated up to 170-175 °C while stirred. After completion of the reaction with 70.4 g EC, the PC (48.9 g, 0.48 mole, pure, Fluka, Buchs, Switzerland) was added and heating was continued. The reaction was monitored by mass balance and by determination of unreacted alkylene carbonate. The products were resin, viscous liquids of brown color. In another synthesis the MPP (4.1 g, 0.02 mole of mer), PC (30.6 g, 0.3 mole), and 0.3 g K2CO3 were used at 185-190 °C temperature. In this case the oily product was contaminated with solid, not converted MPP. 2. 2. Analytical Methods The course of reaction between MPP and EC or PC was followed by measuring the content of unreacted alky-lene carbonate. The samples were treated with 2.5 cm3 of 0.15 M barium hydroxide, vigorously shaken and the excess of barium hydroxide titrated off with 0.1 M HCl solution.15 In obtained products the acid numbers were determined by titration with a standard potassium hydroxide solution and hydroxyl number of the obtained oligoethe-rols was determined with use of acetic anhydride.16 Elemental analysis for C, H, N, were done with EA 1108, Carlo-Erba analyzer. The 1H-NMR spectra of products were recorded at 500 MHz Bruker UltraShield in DMSO-d6 with hexamethyldisiloxane as internal standard. IR spectra were registered on PARAGON 1000 FT IR Perkin Elmer spectrometer in KBr pellets or ATR technique. Thermal analyses of oligoetherols and foams (DTA, DTG and TG) were performed in ceramic crucible at 20-600 °C temperature range, about 200 mg sample, under air atmosphere with Termowaga TGA/DSC 1 derivatograph, Mettler, recording time 100 minutes, 1/10 DTA amplification, and 1/15 DTG amplification. 2. 3. Physical Properties of Oligoetherols Refraction index, density, viscosity, and surface tension of oligoetherols were determined with Abbe refracto-meter, pycnometer, Hoppler viscometer (typ BHZ, prod. Prufgeratewerk, Germany) and by the detaching ring method, respectively. 2. 4. Foam Preparation Oligoetherol (10 g), 2% water, silicone L-6900 (pure, Houdry Hulls, USA) surfactant, and triethylamine (pure, POCH, Poland) catalyst were placed in 500 cm3 cup, homogenized by stirring, then polymeric diphenylmetha-ne 4,4'-diisocyanate (pMDI, containing 30 mass% of three-functional isocyanates, Merck, Darmstadt, Germany) was added and the mixture was stirred mechanically at 1800 rpm until creaming started. Other composi- Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... Acta Chim. Slov. 2016, 63, 77-87 87 tions were also prepared, in which the MPP was added as additive flame retardant after homogenization of oligoet-herol, water, silicone and triethylamine. After homogenization of these mixtures the pMDI was added and further the creaming was performed as described above. 2. 5. Studies of Foams The apparent density,17 water uptake,18 dimensional stability in temperature 150 °C,19 heat conductance coefficient, heat capacity, and compressive strength20 of trPUFs with flame retardants were measured. Thermal resistance of modified foams was determined both by static and dynamic methods. In static method the foams were heated at 150, 175 and 200 °C with continuous measurement of mass loss and determination of mechanical properties before and after heat exposure. Thermal resistance was also determined by dynamic method DSC using differential scanning calorimeter type DSC 822e (METTLER TOLEDO), with the following parameters: temperature range 20-200 °C, heating rate 10 deg / min, nitrogen atmosphere, sample mass 10-20 mg, recording time 100 minutes, DTA 1/10 amplification, and DTG 1/15 amplification. Flammability of foams was determined by oxygen index21 and horizontal test according to norm22 as follows: the foam samples (150 x 50 x 13mm) were weighed, located on horizontal support (wire net of 200 x 80 mm dimensions) and the line was marked at the distance of 25 mm from edge. The sample was set on fire from the opposite edge using Bunsen burner with the blue flame of 38 mm height for 60 s. Then the burner was removed and time of free burning of foam reaching marked line or cease of flame was measured by stopwatch. After that the samples were weighed again. If the sample was burned totally, the rate of burning was calculated according to the expression: (1) If the burning of sample ceased, the following equation was used: (2) where: Le - the length of burned fragment, measured as the difference 150 minus the length of unburned fragment (in mm). According to norms, if the burned fragment has the 125 mm length, the foam is considered as flammable. tb, te - the time of propagation of flame measured at the distance between starting mark up to the end mark or as the time of flame cease. The mass loss A m after burning was calculated from the formula: (3) where mo and m - mean the sample mass before and after burning, respectively. 3. Results and Discussion No hydroxyalkylation of MPP was reported till date, probably due to its insolubility in organic solvents or water. Thus, hydroxyalkylation of MPP cannot be performed by oxiranes in DMSO or DMF, in contrary to melamine.23 It is known that azacyclic compounds with nitrogen-attached hydrogen are soluble in alkylene carbonates and react with them resulting in formation of oligoetherols.24 We have applied this method to derivatize MPP with EC and PC toward oligoetherols (Table 1). Then the oligoetherols were used to obtain PUFs with 1,3,5-triazine ring and phosphorus incorporated into polymer structure. The oligoetherols were synthesized using EC at 170 °C, and PC at 190 °C. Table 1. Synthesis conditions of oligoetherols from MPP and alkylene carbonates (AC) Entry Initial Amount Reaction conditions molar ratio of cata- Tempe- Dissolution Reac- mMPP lyst [g/mol rature time MPP tion time EC: PC mMPP] [°C] [h] [h] Number of moles of AC/ mol mMPP, decomposed* Remarks 1:22:0 1:0:15 1:10:6 20 25 10 170 190 175 3 10 13 23 22 3 1 mole EC 1 mole PC Dark brown resin Dark brown product of unpleasant odor; solid observed in post-reaction mixture Dark brown resin *based upon mass balance mMPP - mere of melamine polyphosphate, AC -alkylene carbonate 1 2 7 3 Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... 80 Acta Chim. Slov. 2016, 63, 77-87 87 However, during the synthesis of oligoetherols from PC is a large weight losses of the reaction mixture by thermal decomposition of PC into carbon dioxide and propylene oxide, which leave the reaction medium. Moreover, in the worked-up post reaction mixture free MPP was found, which in the reaction mixture is suspended in oli-goetherol. Such contaminated and undefined oligoetherols were useless substrates to obtain PUFs. Therefore, consecutive syntheses of oligoetherols were applied; first the MPP was reacted with EC and in the second step the PC was used (Table 1). The amount of EC and PC were minimized to obtain oligoetherols of low viscosity, enabling further homogenization with isocyanates at foaming step. When EC and PC were minimized, the contributions of 1,3,5-triazine ring and phosphorus in the oligoetherol were obviously higher. The obtained oligoetherols were resin-type products. Two kinds of oligoetherols were obtained: with EC only and EC and PC, at initial molar ratio of reagents: mMPP:EC = 1:22, and mMPP:EC:PC = 1:10:6 (mMPP - mere of melamine polyphosphate). Based on mass balance, elemental analysis and hydroxyl numbers in products: 469 and 490 mg KOH/g, respectively (Table 2) it has been concluded that in isolated products the number of oxyalkylene groups per one mMPP was 1:19 and 1:9:5 (Table 2), respectively. Obviously some decomposition of alkylene carbonates in synthetic conditions took place. The scheme of synthesis is summarized as follows: The proposed structure of oligoetherols was verified by IR and 1H-NMR spectra of isolated products. In the IR spectrum of MPP (Fig. 1) the symmetric and asymmetric v(N-H) broad bands at 3400-3100 cm-1 are present. The deformation bands of amine group are present in 1704-1550 cm-1 region. The valence bands of C=N in melamine are in the 1690-1410 cm-1 region, while 1,3,5-triazine ring bands occur at 782 cm-1. Phosphate group bands are at 1338 cm-1 for free P=O group, while the band at 1272 cm-1 belongs to hydrogen-bonded phosphate. The where: f + p + r + t + q + w + x + y + z = n n - numbers of moles of alkylene carbonate which reacted with 1 mole of mMPP. Scheme 3. Synthesis of oligoetherols from melamine polyphosphate and alkylene carbonates. Table 2. Elemental analyses, acid and hydroxyl numbers of obtained oligoetherols Initial molar Molar ratio mMPP; Elemental analysis [% mas] Acidic Hydroxyl ratio mMPP : oxyalkylene groups from Calc. found number number EC : PC z EC and PC in product C H N CH N [mg KOH/g] [mg KOH/g] 1:22:0 1:19:0 46.42 8.02 7.92 46.66 8.38 7.89 8.6 469 1:10:6 1:9:5 47.47 8.24 9.23 47.76 8.44 9.37 12.9 490 Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... Acta Chim. Slov. 2016, 63, 77-87 87 P-O-H group broad band is at 2700-2600 cm-1 and the band from -NH3+ cation at 2700-2250 cm-1. The amine group and ammonium cation bands at the 3400-3100 cm-1 and 2700-2600 cm-1 region respectively are absent in the IR spectra of products of reaction between MPP and alkylene carbonates (Fig. 2). Instead, the v(O-H) bands are present. Also the deformation amine bands at 1660-1570 cm-1 are absent in spectra of products, while C=N bands remain, indicating the presence of 1,3,5-triazi-ne ring in oligoetherols. The bands from P-O-H and NH3+ at 2700-2250 cm-1 disappear in the products, indicating that both amine groups of melamine and phosphate Fig. 1. IR spectrum of MPP residue OH underwent hydroxyalkylation with alkylene carbonates. Low values of acidic number (AN = 8.6-12.9 mg KOH/g) evidence the absence or low content of acidic groups derived from MPP hydrolysis during titration. Nonetheless, in the IR spectra of oligoetherols the bands at 1359-1353 and 1267-1265 cm-1 attributed to free and hydrogen-bonded P=O groups clearly evidence the presence of phosphate in the products, similarly as the band at 752-759 cm-1 region from 1,3,5-triazine ring. Moreover, methylene and methyl group signals at 2860-2970 cm-1 appear in IR spectra of products. These new bands belong to the groups formed upon hydroxyalkylation of MPP. High intensity bands at 1042-1047 cm-1 indicate the presence of ether bond in oligoetherol due to alkylene carbonate ring opening reaction. The 1H-NMR spectra of oligoetherols obtained from MPP and EC are simple (Fig. 3 and 4). The multiplets in the 3.1-3.6 ppm region from methylene protons in oxyethylene groups are diagnostic. The broad singlet at 4.6-4.7 ppm was attributed to -O-H proton by selective deuteration experiment. Olefinic resonance at 4.3 ppm had very low intensity indicating that dehydration of oligoetherols during demanding synthetic conditions was a minor side reaction. In the 1H-NMR spectra of oligoetherols obtained from MPP, EC, and PC (Fig. 4) additional signals from methyl protons are present at 0.95-1.1 ppm region. In fact there are two resonances, one from normal and another one from abnormal PC Fig. 2. IR spectrum of oligoetherol obtained from mMPP:EC=1:22 Fig. 3. 1H-NMR spectrum of oligoetherol obtained from mMPP:EC=1:22 -O-CH-CH-OH + I CH, Scheme 4. PC ring-opening reactions. CH,—CH-CH, /T- 0 Y° © © -CO, © -co, -O-CHr-CH-O-CHrCH-OH I CH, CH, normal structure -O-CH—CH-O-CH-CHjOH CH, I CH, abnormal structure Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... 82 Acta Chim. Slov. 2016, 63, 77-87 87 Fig. 4. 1H-NMR spectrum of oligoetherol from mMPP:EC:PC =1:10:6 ring-opening reactions:25 By integration of these two resonances one can find that there is ca 14% of abnormal pro-duct. Relevant physical properties of oligoetherols were determined, like refraction index density, viscosity, and surface tension (Fig. 5-7). All the properties showed typical temperature dependences. The product containing oxypropylene groups have lower density than those obtained from EC. Also the viscosity of oligoetherol with PC is lower than that with EC, which enables homogenization of foaming composition suitable for obtaining PUFs. Refraction indexes of oligoetherols in temperature 20 °C are similar: 1.5010 for the oligoetherol obtained from m-MPP:EC = 1:22 and 1.5019 for the oligoetherol obtained from mMPP:EC:PC = 1:10:6. We have tested the obtained oligoetherols as substrates for PUFs. We were interested in the effect of flame retardance of PUFs obtained from the oligoetherols MPP-modified as reactive retardant (MPP-PUFs). We have optimized the amount of isocyanate (pMDI) and catalyst for both kinds of MPP-PUFs: those obtained from Fig. 6. Dependence of viscosity in function of temperature for the oligoetherols obtained in molar ratio as shown in insert. Fig. 7. Dependence of surface tension in function of temperature for the oligoetherols obtained in molar ratio as shown in insert. 1,09 -I-1-1-1-1-1-1-1-1-1-1-1-1-[— 20 30 40 50 60 70 80 Temperature [DC] Fig. 5. Dependence of density in function of temperature for the oligoetherols obtained in molar ratio as shown in insert. EC and EC+PC as substrates for oligoetherol. We have found that the best properties of MPP-PUFs were obtained when amount of pMDI in foaming mixture, given as molar ratio of isocyanate to hydroxyl groups (NCO/OH) in foaming mixture was 1.2 (isocyanate coefficient, Table 3, compositions 3 and 7). Considering the optimization of water, the 1% water in foaming mixture led to low foaming, more than 2% led to fragile MPP-PUFs, therefore 2% was the optimum amount. The optimized amount of catalyst was 3.3 g catalyst per 100 g oligoetherol in EC-based compositions, and 6 g in EC-PC - based compositions (Table 3, compositions 3 and 7). Optimized surfactant percentage was between 1.0 and 1.2%. Creaming times were short (below 30 sec); in fully optimized conditions they were within 19-23 seconds. Growing time for optimized compositions was 53 and 26 seconds, respectively. After growing the MPP-PUFs had dry surface. Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... Acta Chim. Slov. 2016, öS, ll-Sl S3 Table 3. The influence of composition on foaming process and characteristics of PUFs Initial molar ratiom MPP:EC: Comp. Amount of co-substrate [g/100g oligoetherol] TEA sili- MPP Molar Foaming Process Time of Time of Time of Characteristics PC No kone ratio creaming expanding drying of foams NCO/OH [s ] [s] 1 16C 11.3 2.4 C 1.4 1C 1C Imm. Rigid 1:22:C 2 14C l.9 2.4 C 1.2 12 5 Imm. Semirigid 3* 14C 3.3 1.C C 1.2 23 53 Imm. Regular pores, rigid 4 112 3.5 2.4 C C.9 13 21 Imm. Irregular pores 5 14C 6.C 1.6 C 1.C 3C 49 Very long Low foaming 1:1C:6 6 14C 5.3 1.6 C 1.C 24 35 10 Large pores l* 16C 6.C 1.2 C 1.2 19 26 10 Regular pores, rigid S 16C 5.C 1.2 C 1.2 25 29 15 Large pores 9 13C 5.3 2.4 45 1.6 1S l9 Very long Viscous surface 1C 116 4.9 2.2 45 1.6 12 26 Imm. Rigid 1:22:C 11* 12C 4.l 1.9 45 1.5 14 16 Imm. Regular pores, rigid 12 124 5.3 2.9 55 1.6 16 3l Imm. Viscous surface, shrinkage 13 12C 4.C 2.4 55 1.C 14 46 10 Small shrinkage 14* 112 6.6 2.4 55 C.9 12 1C Imm. Regular pores, rigid 15 11l 3.l 1.6 45 1.5 14 16 Imm. Large pores 16* 11l 3.4 1.6 45 1.3 1S 39 Imm. Regular pores, rigid 1:1C:6 1l 12C 5.3 1.6 55 C.9 1S l2 Very long Breaks while growing 1S 1CS 5.3 1.6 55 C.S 13 4l Imm. Breaks while growing 19* 1C4 5.C 1.6 55 C.l 14 25 Imm. Regular pores, rigid 2% of water in relation to mass of oligoetherol was used * composition obtained under optimized foaming conditions; pMDI - polymeric diphenylmethane isocyanate, TEA - triethylamine Time of Creaming: the time elapsed from the moment of mixing to the start of volume expansion; Time of Expanding: the time from the start of expansion to the moment of reaching the sample final volume; Time of Drying: the time from reaching by the sample its final volume to the moment of losing its surface adhesion The apparent density, water uptake and linear dimensions before and after thermal exposure of MPP-PUFs at 150 °C were determined (Table 4, compositions 3 and 7). It has been found that apparent density of PUFs was within 59.7-63.7 kg/m3. Water uptake was maximum 11.4%, which indicated that closed pores dominated in obtained materials. Linear dimension stability was monitored after exposure of MPP-PUFs at 150 °C and it was below 0.5% in case of PUF obtained from oligoetherol m-MPP:EC:PC 1:10:6, and 7.6% in case PUFs from m-MPP:EC = 1:22 after 48 hours exposure. The obtained p-UFs had typical heat conductivity within 0.026-0.043 [W/m ■ K] (table 4, compositions 3 and 7). Heat capacity of PUFs was (83-111)103 kJ/m3 ■ K and increases along with heat conductivity. Finally, the thermal resistance of MPP-PUFs was determined by mass loss after one month exposure at 150, 175, and 200 °C together with compressive strength before and after thermal exposure. Static measurements of thermal resistance showed that the largest mass loss was observed at first day of thermal exposure (Fig. 8). The obtained MPP-PUFs are rigid and remain as such after thermal exposure. The foams based on oligoetherol obtained from mMPP:EC = 1:22 deform at 200 °C in contrary to those obtained from MPP:EC:PC = 1:10:6; the first were not tested for compressive strength after exposure. All obtained here MPP-PUFs are less thermally resistant than those obtained from oligoetherols synthesized from mela-mine and alkylene carbonates6 and obtained from carba-zole, glycidol, and alkylene carbonates26. The mass loss of MPP-PUFs described here after 1 month thermal exposure at 150, 175, and 200 °C was 11.3-11.4%, 20.6-23.8% and 38.8% , while those obtained from melamine and PC showed 6.7-8.7, 18.4-22.2, and 29.4-35.0% mass loss6 or those obtained from carbazole, glycidol, and alkylene carbonates: 3.9-5.4, 8.9-10.1 and 17.9-23.4.26 Obtained MPP-PUFs have the compressive strength comparable to classic rigid PUFs. Their compressive strength increases upon thermal exposure at 150 °C and 175 °C, presumably due to additional residual cross-linking (Table 5, compositions 3 and 7). However upon exposure at 200 °C decrease of compressive strength was observed (Table 4, composition 7), though the compressive strength still remained larger than the initial one. Obviously, exposition of the MPP-PUF to 200 °C was accompanied by thermal degradation. Lubczak and Lubczak: Melamine Polyphosphate - the Reactive 84 Acta Chim. Slov. 2016, 63, 77-87 87 Table 4. Properties of PUFs (continued) Foams obtained from oligoetherols MPP No Comp as in Table 3 Density [kg/m3] 5 min Absorb. of Water wt% ] after 3 h 24 h 1 2 3 4 5 6 7 mMPP:EC = 1:22 0 3 59.7 ± 5.2 1.7 3.6 5.6 mMPP: EC:PC = 1:10:6 0 7 63.7 ± 4.3 3.8 7.1 11.4 mMPP:PC = 1:22 45 11 79.0 ± 7.2 7.7 12.7 20.9 55 14 83.1 ± 5.2 7.2 12.4 17.5 mMPP: EC:PC = 1:10:6 45 16 70.5 ± 3.6 7.3 10.7 15.4 55 19 85.5 ± 4.7 7.9 12.3 18.7 Standard deviation in case of designation of Absorbtion of Water and Dimensional Stability does not exceed 1.8, and 1.4%, respectively Table 5. Thermal stability,compressive strength anfd flame properties of foam (continued) Foams obtained from oligoetherols MPP No Comp as in Table 3 Mass loss in% wt. after exposure in one month in temperature [oC] 150 175 200 before exposure 1 2 3 4 5 6 mMPP:EC = 1:22 0 3 11.4 ± 0.2 23.8 ± 0.1 - 0.090 ± 0.004 mMPP:EC:PC = 1:10:6 0 7 11.3 ± 0.1 20.6 ± 0.3 38.8 ± 0.3 0.125 ± 0.007 mMPP:EC = 1:22 45 11 15.0 ± 0.3 25.9 ± 0.2 33.7 ± 0.2 0.410 ± 0.010 55 0.215 ± 0.010 14 13.3 ± 0.2 21.3 ± 0.3 34.7 ± 0.2 mMPP:EC:PC = 1:10:6 45 16 14.7 ± 0.2 24.4 ± 0.3 33.6 ± 0.3 0.201 ± 0.008 55 19 13.9 ± 0.2 20.9 ± 0.2 34.5 ± 0.4 0.259 ± 0.05 a) Î. ▲ * i *: ►i mMPP:EC=i:22 m MPP:EC:PC= 1:10:6 mMPP:EC=1:22 + MPP{55) m MPP:EC:PC= 1:10:5 + MPP (55) mMPP:EC=1:22 + MPP(45) mMPP:EC:PC=1 :10:6 + MPP (45) * I • ' : ..... * ': ; v i : * s Time [day] b) ■ mMPP:EC=1:22 * • mMPP:EC:PC=1:10:6 * mWIPP:ËC=1:22 + MPP (55) ■ * t mMPP:EC:PC=1:10:6 + MPP(55) * « mMPP:EC=1:22+ MPP(45) K » iriMPP:EC:PC=1 10:6+ MPP (45) ► f i. »! »i *** 1 » * i » ■ * ▼ ? î »i rt * i * * ■ ■ . { î Î ► ■ M 4 4 10 15 20 Time [day] Fig. 8. Thermal stability of polyurethane foams as the mass changes after heating at 150 (a), 175 (b) and 200 °C (c) for one month (sample composition is given in insert) Vertical flammability test indicated that MPP-PUFs obtained from oligoetherols based on MPP and alkylene carbonates were self-extinguishing (Table 5, composition 3 and 7, columns 10-12). In the test the flaming distance reached 34-35 mm from ignition line. Their flaming rate was low: 1.30-1.35 mm/s, while that of PUFs containing 1,3,5-triazine ring was as high as 5.6-6.4 mm/s.27 Characte- ristically self-extinguishing was accompanied by low mass losses upon flaming: 4.9-7.5% . However, their oxygen index was not very promising (21.9). Therefore further modification of powdered MPP-based PUFs was performed. The MPP was additionally used as additive flame retardant. Effectively, as much as 45 g of MPP (per 100 g of oligoetherol) could be introduced into composition of Lubczak and Lubczak: Melamine Polyphosphate - the Reactive ... Acta Chim. Slov. 2016, 63, 77-87 87 Dimensional Stability [%] in temperature 150 °C Length Width Hight Heat conductance Heat change change change coefficient capacity [%] [%] [%] [W/m • K] [kJ/m3 • K] 103 20 h 40 h 20 h 40 h 20 h 40 h 8 9 10 11 12 13 14 -1.6 -2.1 -3.9 -4.9 -6.7 -7.6 0.0260 ± 0.0005 83.0 ± 0.4 -0.3 -0.2 -0.5 -0.4 -0.2 -0.2 0.0430 ± 0.0007 111.0 ± 1.0 -0.7 -0.7 -0.2 -.03 -0.1 -0.7 0.0378 ± 0.0000 115 ± 1.3 -0.1 -0.7 -0.1 -0.4 -0.1 -0.5 0.0470 ± 0.00010 145 ± 1.7 -0.4 -0.6 -2.0 -3.0 -1.1 -4.2 0.0370 ± 0.0016 148 ± 1.9 -0.5 -0.6 -0.1 -0.3 -0.1 -0.3 0.0440 ± 0.0006 207 ± 1.7 Compressive strength [MPa]* Flame Flame Mass loss Oxygen after exposure zone rate upon flaming index in temperature [mm] [mm/s] [% mas.] [%] 150 175 200 7 8 9 10 11 12 13 0.157 ± 0.005 0.365 ± 0.015 - 34 ± 3.0 1.35 ± 0.10 7.5 ± 0.9 21.9 ± 0.1 0.181 ± 0.007 0.216 ± 0.011 0.179 ± 0.008 35 ± 2.0 1.30 ± 0.04 4.9 ± 0.5 21.9 ± 0.1 0.347 ± 0.013 0.025 ± 0.009 0.017 ± 0.002 6.0 ± 0.5 - 2.1 ± 0.4 23.8 ± 0.2 0.583 ± 0.010 0.344 ± 0.017 - 5 ± 0.5 - 0.9 ± 0.2 24.2 ± 0.1 0.181 ± 0.05 0.092 ± 0.005 0.017 ± 0.001 5.0 ± 0.4 - 3.0 ± 0.2 24.4 ± 0.1 0.484 ± 0.012 0.202 ± 0.007 - 7.0 ± 0.4 - 1.5 ± 0.2 24.6 ± 0.0 The water uptake increase of composite was due to presence of polar MPP physical admixture in composite. Linear dimension of composites do not change considerably upon thermal exposure; they are up to 4.2% after exposure at 150 °C. Heat conductance coefficient of composites was 0.0370-0.0470 W/m ■ K and increases along with MPP percentage in composite. It is generally larger than that of PUFs without MPP added as physical component, which might be consistent with higher water uptake of composites. Mass loss of composites MPP@MPP-PUF upon thermal exposures at 150 °C, 175 °C, and 200 °C are: 13.3-15.0% , 20.9-25.9% , and 33.6-34.7%, respectively (Table 5, compositions 11, 14, 16 and 19, columns 3-5). Moreover, the mass losses of composites do not depend on added MPP. However, they are higher than corresponding PUFs without additive MPP. The mass losses of composites upon exposition at 150 C and 175 °C are 4-5% higher than those for MPP-PUFs. MPP@MPP-PUFs have considerably larger compressive strength than those of MPP-PUFs before thermal exposure. The composites MPP @ MPP-PUFs with 45 g MPP/100 g of oligoet-herol in compositions do not deform upon heating at 200 °C in contrary MPP-PUFs. On the other hand these composites lose their compressive strength upon thermal exposure (Table 5, compositions 11 and 16). Composites c) 95 -90 - ■—■ as IS