Certificate of Accreditation

PERRY JOHNSON LABORATORY ACCREDITATION, INC. Certificate of Accreditation Perry Johnson Laboratory Accreditation, Inc. has assessed the Laboratory of: Comercializadora y Servicios Técnicos Súper L, S.A de C.V. Leandro Valle #36, Col. Ciudad Adolfo López Mateos, Atizapán de Zaragoza, Estado de México, México. CP. 52900 (Hereinafter called the Organization) and hereby declares that Organization is accredited in accordance with the recognized International Standard: ISO/IEC 17025:2005 This accreditation demonstrates technical competence for a defined scope and the operation of a laboratory quality management system (as outlined by the joint ISO-ILAC-IAF Communiqué dated January 2009): Dimensional, Thermodynamic, Mass, Force and Weighing Devices and Mechanical Calibration (As detailed in the supplement) Accreditation claims for such testing and/or calibration services shall only be made from addresses referenced within this certificate. This Accreditation is granted subject to the system rules governing the Accreditation referred to above, and the Organization hereby covenants with the Accreditation body s duty to observe and comply with the said rules. For PJLA: Initial Accreditation Date: Issue Date: Expiration Date: December 26, 2014 January 31, 2017 March 30, 2019 Tracy Szerszen President/Operations Manager Perry Johnson Laboratory Accreditation, Inc. (PJLA) 755 W. Big Beaver, Suite 1325 Troy, Michigan 48084 Accreditation No.: Certificate No.: 56697 L17-38 The validity of this certificate is maintained through ongoing assessments based on a continuous accreditation cycle. The validity of this certificate should be confirmed through the PJLA website: www.pjlabs.com Page 1 of 5

Comercializadora y Servicios Técnicos Súper L Atizapán de Zaragoza, Estado de México, Mexico C.P.52900 Dimensional Bore Diameter O Melt Index Piston Rod Diameter O Piston Foot Diameter O Piston Foot Length O Orifice Length O Switch Travel O Orifice I/D O Strain Verification (Extensometer) O AND 0.375 7 in to 0.376 3 in 0.000 17 in Bore Gauge 0.310 in to 0.351 in 0.000 14 in Micrometer Check at 23 C +/- 5 C 0.372 7 in to 0.373 3 in 0.000 18 in Micrometer 0.245 in to 0.255 in 0.000 58 in Micrometer 0.314 in to 0.316 in 0.000 58 in Micrometer 0.809 in to 1.811 in 0.000 43 in Switch Calibrator 0.082 3 in to 0.082 7 in 0.002 6 in Go/No Go 0.000 05 in to 1 in 0.000 1 in Cal 60 ASTM E83 Thermodynamic Bore Temperature O AND 90 C to 400 C 0.15 C Digital Thermometer of precision Mass, Force and Weighing Devices Weigth and Piston Rod O AND 100 g to 10 100 g 0.2 % of reading Balance (of the selected load for the test) Issue: 01/2017 This supplement is in conjunction with certificate #L17-38 Page 2 of 5

Mechanical Rockwell Hardness Testers HRB O Rockwell Hardness Testers HRC O Brinell Hardness Tester HBW 10/3000 FO Micro Hardness Tester Vickers O Micro Hardness Tester Knoop O Calibration of Durometer Hardness F Tester (SHORE) Types: A,B,C,D,E,DO,O,OO & OOO Extension at Zero reading Indenter Shore Durometer Extension Indentor 0 to 100Shore) AND CAPABILITY EXPRESSED AS AN UNCERTAINTY (±) 40 HRB to 59 HRB 0.51 HRB Rockwell Standardized Hardness 60 HRB to 79 HRB 0.41 HRB Test Block ASTM E18-08A 80 HRB to 100 HRB 0.39 HRB ISO 6508-20 HRC to 30 HRC 0.28 HRC 35 HRC to 58 HRC 0.28 HRC 60 HRC to 65 HRC 0.27 HRC 92.5 HBW to 650 HBW 3.02 HBW Brinelll Standardized Hardness Test Block ASTM E10 ISO 6506 100 HV0.5 to 900 HV0.5 4.9 HV Standardized Hardness Test Block ASTM E384 100 HK0.5 to 900 HK0.5 4.4 HK Standardized Hardness Test Block ASTM E384 2.46 mm to 2.54 mm 0.004 2 mm (4.2 μm) Dial Gage Tester Mitutoyo Model. 170-102M-2 ASTM D2240 Force Type A, B, E & O 1.30 N to 8.05 N Force Type C, D, & DO 4.445 N to 44.45 N Balance ASTM D2240 Force Type OO & OOO 0.203 N to 1.111 N Issue: 01/2017 This supplement is in conjunction with certificate #L17-38 Page 3 of 5

Mechanical Testing Machines and Force Instruments - Tensile FO Testing Machines and Force Instruments - Compresion FO DEVICE SIZE AS AND CAPABILITY EXPRESSED 0.01 N to 100 N 0.037 % of reading Dead Weights ISO-7500-1 0.099 97 kn to 0.999 8 kn 0.053 % of reading Load Cell ISO-7500-1 0.980 7 kn to 9.807 kn 0.054 % of reading Load Cell ISO-7500-1 9.807 kn to 98.070 kn 0.056 % of reading Load Cell ISO-7500-1 29.420 kn to 294.2 kn 0.048 % of reading Load Cell ISO-7500-1 0.01 N to 100 N 0.037 % of reading Dead Weights ISO-7500-1 0.099 97 kn to 0.999 8 kn 0.026 % of reading Load Cell ISO-7500-1 0.980 7 kn to 9.807 kn 0.027 % of reading Load Cell ISO-7500-1 9.807 kn to 98.070 kn 0.065 % of reading Load Cell ISO-7500-1 98.07 kn to 980.7 kn 0.027 % of reading Load Cell ISO-7500-1 29.42 kn to 294.2 kn 0.099 % of reading Load Cell ISO-7500-1 294.2 kn to 2 942 kn 0.057 % of reading Load Cell ISO-7500-1 Issue: 01/2017 This supplement is in conjunction with certificate #L17-38 Page 4 of 5

1. The CMC (Calibration and Measurement Capability) stated for calibrations included on this scope of accreditation represents the smallest measurement uncertainty attainable by the laboratory when performing a more or less routine calibration of a nearly ideal device under nearly ideal conditions. It is typically expressed at a confidence level of 95 % using a coverage factor k (usually equal to 2). The actual measurement uncertainty associated with a specific calibration performed by the laboratory will typically be larger than the CMC for the same calibration since capability and performance of the device being calibrated and the conditions related to the calibration may reasonably be expected to deviate from ideal to some degree. 2. The laboratories range of calibration capability for all disciplines for which they are accredited is the interval from the smallest calibrated standard to the largest calibrated standard used in performing the calibration. The low end of this range must be an attainable value for which the laboratory has or has access to the standard referenced. Verification of an indicated value of zero in the absence of a standard is common practice in the procedure for many calibrations but by its definition it does not constitute calibration of zero capacity. 3. The presence of a superscript F means that the laboratory performs calibration of the indicated parameter at its fixed location. Example: Outside Micrometer F would mean that the laboratory performs this calibration at its fixed location. 4. The presence of a superscript O means that the laboratory performs calibration of the indicated parameter onsite at customer locations. Example: Outside Micrometer O would mean that the laboratory performs this calibration onsite at the customer s location. 5. The presence of a superscript FO means that the laboratory performs calibration of the indicated parameter both at its fixed location and onsite at customer locations. Example: Outside Micrometer FO would mean that the laboratory performs this calibration at its fixed location and onsite at customer locations. 6. Measurement uncertainties obtained for calibrations performed at customer sites can be expected to be larger than the measurement uncertainties obtained at the laboratories fixed location for similar calibrations. This is due to the effects of transportation of the standards and equipment and upon environmental conditions at the customer site which are typically not controlled as closely as at the laboratories fixed location. Issue: 01/2017 This supplement is in conjunction with certificate #L17-38 Page 5 of 5