Source: https://www.scribd.com/document/315010217/OIML-R-76-2
Timestamp: 2019-04-25 18:40:40
Document Index: 123422769

Matched Legal Cases: ['art 20', 'Application no.3', 'Application no.4', 'Application No.1', 'Application no. 12', 'Application no.3']

OIML R 76-2 | Power Supply | Electricity
OIML R 76-2
Uploaded by Francisco Leal
Digitalizador Placas Rx Regius 190
JCOO-7AJS6M_R0_EN
Yleisohje English
Edition 2007 (E)
OIML R 76-2 Edition 2007 (E)
Partie 2: Format du rapport d'essai
OIML R 76-2: 2007 (E)
Foreword ................................................................................................................................................................ 3
Introduction ............................................................................................................................................................. 4
Explanatory notes .................................................................................................................................................... 5
General information concerning the type ................................................................................................................ 6
Information concerning the test equipment used for type evaluation ...................................................................... 8
Summary of type evaluation .................................................................................................................................... 9
Weighing performance ............................................................................................................................ 10
Temperature effect on no-load indication................................................................................................ 11
Eccentricity.............................................................................................................................................. 12
Eccentricity using weights....................................................................................................................... 12
Eccentricity using a rolling load .............................................................................................................. 13
Discrimination and sensitivity ................................................................................................................. 14
Discrimination ......................................................................................................................................... 14
Sensitivity (non-self-indicating instrument) ............................................................................................ 15
Repeatability............................................................................................................................................ 16
Time-dependence..................................................................................................................................... 17
Zero return ............................................................................................................................................... 17
Creep ....................................................................................................................................................... 18
Stability of equilibrium............................................................................................................................ 19
Tilting ...................................................................................................................................................... 20
Tare (weighing test)................................................................................................................................. 21
Warm-up time.......................................................................................................................................... 22
Voltage variations.................................................................................................................................... 23
Electrical disturbances............................................................................................................................. 24
AC mains voltage dips and short interruptions........................................................................................ 24
Electrical bursts ....................................................................................................................................... 25
Surges ...................................................................................................................................................... 27
Electrostatic discharges ........................................................................................................................... 29
Immunity to radiated electromagnetic fields ........................................................................................... 32
Immunity to conducted radio-frequency fields........................................................................................ 34
Disturbance tests for instruments powered from a road vehicle power supply........................................ 35
Damp heat, steady state ........................................................................................................................... 37
Span stability ........................................................................................................................................... 40
Endurance ................................................................................................................................................ 46
Examination of the construction of the instrument.................................................................................. 48
Checklist .................................................................................................................................................. 49
All types of weighing instruments except non-self-indicating instruments............................................. 50
Instruments for direct sales to the public and price computing and labeling instruments ....................... 57
Electronic weighing instruments ............................................................................................................. 60
Software-controlled digital devices and instruments ............................................................................... 61
The International Organization of Legal Metrology (OIML) is a worldwide, intergovernmental organization
whose primary aim is to harmonize the regulations and metrological controls applied by the national
metrological services, or related organizations, of its Member States. The main categories of OIML
International Recommendations (OIML R), which are model regulations that establish the
metrological characteristics required of certain measuring instruments and which specify methods
and equipment for checking their conformity. OIML Member States shall implement these
Recommendations to the greatest possible extent;
International Documents (OIML D), which are informative in nature and which are intended to
harmonize and improve work in the field of legal metrology;
International Guides (OIML G), which are also informative in nature and which are intended to
give guidelines for the application of certain requirements to legal metrology; and
International Basic Publications (OIML B), which define the operating rules of the various OIML
OIML Draft Recommendations, Documents and Guides are developed by Technical Committees or
Subcommittees which comprise representatives from the Member States. Certain international and regional
institutions also participate on a consultation basis. Cooperative agreements have been established between
the OIML and certain institutions, such as ISO and the IEC, with the objective of avoiding contradictory
requirements. Consequently, manufacturers and users of measuring instruments, test laboratories, etc. may
simultaneously apply OIML publications and those of other institutions.
International Recommendations, Documents, Guides and Basic Publications are published in English (E) and
translated into French (F) and are subject to periodic revision.
Additionally, the OIML publishes or participates in the publication of Vocabularies (OIML V) and
periodically commissions legal metrology experts to write Expert Reports (OIML E). Expert Reports are
intended to provide information and advice, and are written solely from the viewpoint of their author,
without the involvement of a Technical Committee or Subcommittee, nor that of the International Committee
of Legal Metrology. Thus, they do not necessarily represent the views of the OIML.
This publication – reference OIML R 76-2, Edition 2007 – was developed by Technical Subcommittee
TC 9/SC 1 Non-automatic weighing instruments. It was approved for final publication by the International
Committee of Legal Metrology in 2007 and supersedes the previous edition of R 76-2 (1993).
OIML Publications may be downloaded from the OIML web site in the form of PDF files. Additional
information on OIML Publications may be obtained from the Organization’s headquarters:
11, rue Turgot – 75009 Paris – France
33 (0)1 48 78 12 82
g. Electrical tests. In the framework of the OIML Certificate System for Measuring Instruments. These tests are described in Annexes A and B of R 76-1. in a standardized format. a multiple range instrument shall be tested separately for each range and a separate form (including the general information form) shall be filled out for each range. the subject of R 76-2. the results of the various tests to which a type of a non-automatic weighing instrument shall be submitted with a view to its approval. reference number for purpose of traceability). each test being reported individually on a separate page following the relevant format. type and no. use of this report format is mandatory..” at the bottom of the pages of this publication. Description of the procedure of field calibration for the test of immunity to radiated electromagnetic fields. in particular. All metrology services or laboratories evaluating types of non-automatic weighing instruments according to R 76-1 or to national or regional regulations based on OIML R 76-1 are strongly advised to use this “Type evaluation report”. traceability and no.). The information may be a short list containing only essential data (name. type. in French and/or in English with translation into the national languages of the countries issuing such certificates. it is advisable to complete the sequential numbering of each page by the indication of the total number of pages of the report. type.). in the same way. Note concerning the numbering of the following pages In addition to a sequential numbering: “R 76-2 page .or multi-lateral co-operation agreements. and the OIML Mutual Acceptance Arrangement (MAA).. Simulator for testing of modules (name.. a special place is left at the top of each page (starting with the following page) for numbering the pages of reports established following this model.). For example:      Verification standards (accuracy. under bi. Its direct use in English or in French. 4 .OIML R 76-2: 2007 (E) Introduction The “Type evaluation report”. some tests (e. or in both languages. The “information concerning the test equipment used for type evaluation” shall cover all test equipment which has been used in determining the test results given in a report. bursts (name of the instrument. Climatic test and static temperature chamber (name.). weighing performance) shall be repeated several times. aims at presenting. is even more strongly recommended whenever test results may be transmitted by the country performing these tests to the approving authorities of another country. and no. For a given report. type and no. or accuracy class.. if appropriate. directly or after translation into a language other than English or French.
X – X – The white spaces in boxes in the headings of the report should always be filled in according to the following example: Temp. Numbers in brackets refer to the corresponding subclauses of OIML R 76-1. an appropriate explanation shall be given in the column “Yes (remarks)”. or that they result from circumstances such that these faults shall not be considered as significant (see T.: Time: Bar. Non-automatic weighing instruments Type evaluation report EXPLANATORY NOTES Meaning of symbols: I In L ΔL P E Ec mpe EUT = Indication = nth indication = Load = Additional load to next changeover point = I + ½ e – ΔL = Indication prior to rounding (digital indication) = I – L or = P – L or = I + ½ e – ΔL – L = Error = Corrected error = Maximum permissible error (absolute value) = Equipment under test when the instrument has passed the test: when the instrument has failed the test: when the test is not applicable: FAILED For each test. = barometric pressure (barometric pressure is necessary for the span stability test and when specified by IEC test provisions. pres.: At start 20.5. h. In the disturbance tests (12. 5 .6 in R 76-1).5 At max At end 21.OIML R 76-2: 2007 (E) Report page …. = relative humidity Bar.5. “Date” in the test report refers to the date on which the test was performed.: Rel. h. in other cases it may be necessary only for class I instruments). pres.2 °C % hPa where: Temp. = temperature Rel. faults greater than e are acceptable provided that they are detected and acted upon. the “SUMMARY OF TYPE EVALUATION” and the “CHECKLIST” shall be completed according to this example: PASSED The name(s) or symbol(s) of the unit(s) used to express test results shall be specified in each form./….1 through 12.7).
……………… ..………………………..………………….. …... ……………………………......………………………... Date of report: ……………………………. 6 .. Please note that the class denominations used hereafter in this Recommendation do not include the oval around the number for improved clarity of the Test Report Format’s text..…………………....... Interfaces (number. ….. Remarks: ….……………………….. ….......………………..………………….……………………….....…. …………………………….……………… .... …..……………………….………………. ……………………………..……………….... …………………………….. The test equipment (simulator or a part of a complete instrument) connected to the module shall be defined in the test form(s) used....……………… ......../…...……………… .……… ……….. 2 Battery. …..: Type designation: Manufacturer: Applicant: Instrument category: .OIML R 76-2: 2007 (E) Report page ….: Software version: Connected equipment: 1 Hz Tare device: Non-automatic Printer: f= °C No connection Load cell: Manufacturer: Type: Capacity: Number: Classification symbol: ….………………....………………………...... Evaluation period: ……………………………........ nature): …………………………….... …. ……………………………...... Observer: …………………………….……………………….. Unom = % of Max Instrument submitted: Identification no.. …...……………… Module 1 with Complete instrument error fraction pi = Accuracy class 2: Self-indicating Semi-self-indicating Non-self-indicating Min = e= Max = d= n= e1 = e2 = e3 = Max1 = Max2 = Max3 = d1 = d2 = d3 = n1 = n2 = n3 = T=+ Unom = V T=– Umin = Zero-setting device: V Umax = V Tare balancing Semi-automatic Tare weighing Automatic zero-setting Preset tare device Initial zero-setting Subtractive tare Zero-tracking Additive tare Initial zero-setting range = V Built-in Combined zero/tare device Temperature range: Connected Not present but connectable …………………….……………………….…………………... General information concerning the type Application no......…………………..……………….………………....………………………... ….………………………..
OIML R 76-2: 2007 (E) Report page ….1 a or 5. General information concerning the type (continued) Use this space to indicate additional remarks and/or information: Connection equipment.1. interfaces and load cells./….1 b of R 76-1).1. choice of the manufacturer regarding protection against disturbances (5. 7 . etc.
/…. Information concerning the test equipment used for type evaluation 8 .OIML R 76-2: 2007 (E) Report page ….
2 7 8 9 10 11 12.…………………………………………… Report page Application no. b) Test at high temperature and 85 % relative steady state humidity c) Final test (at reference temperature) Span stability a) Initial test Endurance c) Final test EXAMINATIONS Examination of the construction Checklist Remarks: 9 FAILED Tests PASSED ……………………………...OIML R 76-2: 2007 (E) Report page …./….…………………………… ……………….5 12.2 12. Summary of type evaluation 1 2 3..2 4.6 12.1 4..7 13 14 15 16 17 Weighing performance Initial °C °C °C °C °C °C °C Temperature effect on no-load indication Eccentricity using weights Eccentricity using a rolling load Discrimination Sensitivity Repeatability Zero return Creep Printing. tare balancing Tilting Tare Warm-up time Voltage variations AC mains voltage dips and short interruptions a) Mains power supply lines Electrical bursts b) I/O circuits and communication lines a) AC mains power supply Surges b) Any other kind of power supply lines a) Direct application Electrostatic discharges b) Indirect application (contact discharges only) Immunity to radiated electromagnetic fields Immunity to conducted radio-frequency fields a) Conduction along supply lines of external Electrical transients on 12 V and 24 V batteries instruments powered from a b) Capacitive and inductive coupling via lines road vehicle power supply other than supply lines a) Initial test (at reference temperature) Damp heat. storage Stability of equilibrium Zero-setting.4 12.2 5 6.1 3.1 6.3 12.1 12.: Type designation: Remarks .
1) (Calculation of the error) Application no.3. Ec ↑ ↓ ↑ mpe . pres.: (only class I) ………………………………………… At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Initial zero-setting > 20 % of Max: Out of working range Yes No (see R 76-1.4.4.: Type designation: Date: Observer: Verification scale interval. L ↓ ↑ ↓ ↑ * Error.4.: Rel. ………………………………………… At start ………………………………………… Temp. e: Resolution during test (smaller than e): ………………………………………………….: ………………………………………… Time: Bar. h.5. I ΔL Load.OIML R 76-2: 2007 (E) 1 Report page …. A.4) (A. E ↓ * Check if |Ec| ≤ |mpe| Passed In operation Failed Remarks: 10 Corrected error./…. load. WEIGHING PERFORMANCE (A. …………………………………………………. Indication.2) E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add.
3.: Type designation: Date: Observer: Verification scale interval. for two consecutive tests at different temperatures Check if the zero-change per 5 °C is smaller than e (class II.2) Application no... load. Zero-change per … °C ΔP = difference of P for two consecutive tests at different temperatures ΔTemp. = difference of Temp. (°C) I ΔL P ΔP ΔTemp. Add.5. …………………………………………………………………………………. III or IIII) Check if the zero-change per 1 °C is smaller than e (class I) Passed Failed Remarks: * Give the report page of the relevant weighing test where weighing tests and temperature effect on no-load indication test are conducted together (see R 76-1.OIML R 76-2: 2007 (E) 2 Report page …./…. Figure 11). TEMPERATURE EFFECT ON NO-LOAD INDICATION (A. e: Resolution during test (smaller than e): …………………………………………………………………………………. ………………………………………… ………………………………………… ………………………………………… ………………………………………… Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range In operation P = I + ½ e – ΔL Report page* Date Time Temp Zero indication. 11 .
4.4. Indication. load.1.OIML R 76-2: 2007 (E) 3 3. 1 2 4 3 Also indicate in the sketch the location of the display or of another perceptible part of the instrument.5): 2) In case of “Yes” to 1): A.4. Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* determined prior to each measurement Add. ECCENTRICITY (A. Location Load. …………………………………………………. e: Resolution during test (smaller than e): ………………………………………………….: ………………………………………… Time: Bar.5) under “Remarks” At max At end °C % hPa Yes Yes No No Location of test loads: mark on a sketch (see example below) the successive locations of test loads. L I E ΔL * * * * * * * * 1 2 3 4 Check if |Ec| ≤ |mpe| Passed Failed Remarks: 12 Corrected error.7.7.7. Ec mpe .7 and A. ………………………………………… At start ………………………………………… Temp.7.4.4.7.: ………………………………………… (only class I) 1) Test(s) performed on a mobile instrument (A.4.1 Report page …. 2 and 3) Application no.4 have been applied: 3) In case of “No” to 2): Description of eccentricity test(s) (see A. Error.4.: Rel.1 to A. using numbers which shall be repeated in the table below.: Type designation: Date: Observer: Verification scale interval.7) Eccentricity using weights (A. h./…. pres.
4.OIML R 76-2: 2007 (E) 3. E * * * * * * * * Check if |Ec| ≤ |mpe| Passed Add. L Indication.: Type designation: Date: Observer: Verification scale interval. h. ………………………………………… At start ………………………………………… Temp. 1 2 3 Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Section Direction (Å / Æ) Location Load. pres. e: Resolution during test (smaller than e): …………………………………………………. load./….2 Report page …. Also indicate in the sketch the location of the display or of another perceptible part of the instrument. Ec mpe .: ………………………………………… Time: Bar.: Rel. I Error. …………………………………………………. ΔL Failed Remarks: 13 Corrected error.4) Application no. Eccentricity using a rolling load (A.: ………………………………………… (only class I) Number of sections of the divided load receptor At max At end °C % hPa Undivided load receptor Location of test loads for each section of the load receptor: mark on a sketch (see example below) the successive locations of test loads. using numbers which shall be repeated in the table below.7.
.……… Time: ……………………………. L ………………………………………………….OIML R 76-2: 2007 (E) Report page ….8. d: Load.2) Application no. I2 I2 – I1 Check if I2 – I1 ≥ d Passed Failed Remarks: 4.8. I1 Extra load = |mpe| Check if I2 – I1 ≥ 0.1.: Type designation: Date: Observer: Verification scale interval. 4 DISCRIMINATION AND SENSITIVITY 4.4.. L ………………………………………………….… Rel.1) Application no.: …………………………….2 Analog indication (A.1 Digital indication (A.……… Bar. d: Load.: Removed load ΔL Indication.: Indication.4 d At start At max At end °C % hPa Indication. …………………………………… Temp.……… Bar. e: Scale interval.. pres.: Type designation: Date: Observer: Verification scale interval.1. h.… Rel. I2 At start At max At end °C % hPa I2 – I1 .: …………………………………. I1 Add 1/10 d Extra load. h. …………………………………………………..7 mpe Passed Failed Remarks: 14 Indication. e: Scale interval./….……… Time: …………………………….: …………………………….. pres.1 Discrimination 4.4..: …………………………………. = 1. …………………………………… Temp. ………………………………………………….
………………………………………… ………………………………………… Temp.: Load.4.3 Non-self-indicating instrument (A./…. = 0. …………………………………………………. 4. ………………………………………………….4.: Rel. I * At start At max At end °C % hPa Visible displacement* Mark a visible displacement by “+” Check if there is a visible displacement Passed Failed Remarks: 4.: Type designation: Date: Observer: ………………………………………………….: Type designation: Date: Observer: …………………………………………………. ………………………………………… ………………………………………… Temp: Rel. h: ………………………………………… Time: ………………………………………… Bar.OIML R 76-2: 2007 (E) Report page ….2 Sensitivity (non-self-indicating instrument) (A.: ………………………………………… Time: ………………………………………… Bar. pres: Load L Extra load = |mpe| At start hPa mm mm Passed Failed Remarks: 15 At end °C % Permanent displacement of indicating element mm Check if the permanent displacement is equal to or greater than: 1 mm for an instrument of accuracy class I or II 2 mm for an instrument of accuracy class III or IIII with Max ≤ 30 kg 5 mm for an instrument of accuracy class III or IIII with Max > 30 kg At max .1) Application no. pres. h.8. L Extra load.9) Application No.1.4 |mpe| Indication.
: ………………………………………… Time: Bar. I E 1 11 2 12 3 13 4 14 5 15 6 16 7 17 8 18 9 19 10 20 Add.6 of R 76-1) b) Emax – Emin ≤ absolute value of mpe (3.4.: ………………………………………… (only class I) At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent In operation Load (weighing 1-10) Load (weighing 11-20) E= I + 1/2 e – ΔL – L Indication of load. load. pres.1 of R 76-1) Failed Remarks: 16 E .6.10) Application no. h.OIML R 76-2: 2007 (E) 5 Report page …. e: Resolution during test (smaller than e): …………………………………………………./…. ΔL Emax – Emin (weighing 1-10) Emax – Emin (weighing 11-20) mpe mpe Check if Passed a) E ≤ mpe (3.: Rel. load. ΔL Indication of load. I Add. ………………………………………… At start ………………………………………… Temp. REPEATABILITY (A. ………………………………………………….: Type designation: Date: Observer: Verification scale interval.
e: Resolution during test (smaller than e): …………………………………………………. I0 Add. L0 Time of reading Indication of zero.OIML R 76-2: 2007 (E) 6 6./…. load. TIME-DEPENDENCE Zero return (A.2) Application no. h: ………………………………………… Time: Bar. pres: (only class I) ………………………………………… At max At end Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range P = I + ½ e – ΔL Load.11. ΔL 0 min P P0 = Load during 30 minutes = 30 min P30 = For multiple range instruments keep instrument unloaded for further 5 minutes: P35 = 35 min Check if Passed a) |Δ(P30 – P0) | ≤ 0.4.5 e b) |Δ(P35 – P30) | ≤ e1 (for multiple range instruments only) Failed Remarks: 17 Change after 30 minutes: |Δ(P30 – P0)| = Change 5 minutes later: |Δ(P35 – P30) | = °C % hPa . …………………………………………………. ………………………………………… At start ………………………………………… Temp: Rel.1 Report page ….: Type designation: Date: Observer: Verification scale interval.
1) Application no. pres: ………………………………………… (only class I) At max At end °C % hPa P = I + ½ e – ΔL Load.5 e after 30 minutes.2 e between the indication obtained at 15 minutes and that at 30 minutes Condition b): ΔP ≤ absolute value of mpe during the period of 4 hours Check if condition a) or b) is fulfilled Passed Failed Remarks: 18 . I P ΔP 0 min 5 min 15 min 30 min* 1h 2h 3h 4h ΔP = difference between P at the start (0 min) and P at a given time. * If condition a) is met. the test shall be continued for the next 3. ………………………………………………….5 hours and condition b) shall be met.4. and ΔP ≤ 0. If not. h: ………………………………………… Time: Bar.OIML R 76-2: 2007 (E) 6. load.2 Report page …. e: Resolution during test (smaller than e): …………………………………………………. the test is terminated. L Time of reading Add. Condition a): ΔP ≤ 0. ΔL Indication.: Type designation: Date: Observer: Verification scale interval. Creep (A./…. ………………………………………… At start ………………………………………… Temp: Rel.11.
L0** (10 e) E0 = I0 + ½ e – ΔL – L0 Indication. ………………………………………………….6. I0 after zero-setting Add.2 of R 76-1. ………………………………………… At start ………………………………………… Temp: Rel. L0 shall be applied after releasing tare or zero-setting. e: Resolution during test (smaller than e): …………………………………………………. Perform this five times. STABILITY OF EQUILIBRIUM (A.25 e Passed Failed Remarks: 19 . Load (about 50 % of Max) First printed or stored weight value after disturbance and command Reading during 5 s after print-out or storage minimum value maximum value 1 2 3 4 5 Check if the first printed or stored weight value does not deviate more than 1 e from the readings during 5 seconds after print-out or storage (only two adjacent values allowed) Passed Failed In the case of zero-setting or tare balancing: Zero-setting Zero-load No.: Type designation: Date: Observer: Verification scale interval. ΔL Error.4. I0. disturb the equilibrium and immediately release zero-setting or tare. load. apply L0 if necessary and calculate the error according to A.3/A. ΔL Error. Check if E0 ≤ 0. pres: ………………………………………… (only class I) At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range In operation In the case of printing or data storage: No.* (< 4 % of Max) 1 Load.2.12) Application no. immediately after zero is displayed the first time.4. L0 (10 e) after tare balancing ** 2 3 4 5 * Apply the zero or tare load. E0 2 3 4 5 Tare balancing Tare load No.OIML R 76-2: 2007 (E) 7 Report page …. h: ………………………………………… Time: Bar. E0 Add.4. load. ** L0 (10 e) shall be applied only if an automatic zero-setting or zero-tracking device is in operation.* (about 30 % of Max) 1 E0 = I0 + ½ e – ΔL – L0 Indication. Load./….
: Rel. ………………………………………………….OIML R 76-2: 2007 (E) 8 Report page ….: ………………………………………… Time: Bar.: Type designation: Date: Observer: Verification scale interval. 3. 4.5. pres./….1-A. 5). Automatic zero-setting and zero-tracking device is: Non-existent Ev = Iv + ½ e – ΔLv – L Ec v = Ev – Ev 0 Not in operation Out of working range (v = 1.1.: ………………………………………… (only class I) At max At end °C % hPa Instrument with leveling device and level indicator Instrument with automatic tilt sensor Instrument without level indicator or automatic tilt sensor Mobile instrument with automatic tilt sensor Mobile instrument with Cardanic suspension Limiting value of tilting = Give (if appropriate on a separate sheet) a sketch of the load receptor showing the location of the level indicator or direction of the tilting. if they are not used for direct sales to the public) ≤ absolute value of mpe for the loaded instrument Failed Remarks: 20 . Iv = Indication.1. if provided. A. 2. L 1 unloaded 2 3 (Max) 2e= |E1 0 – Ev 0|max = Iv = ΔLv = Ev = mpe = Ec v = |Ec 1 – Ec v|max = Iv = ΔLv = Ev = mpe = Ec v = |Ec 1 – Ec v|max = Check if the differences are a) b) Passed 5 Iv = ΔLv = Ev0 = L= 4 ≤ 2 e for the unloaded instrument (not valid for class II instruments.5.1. e: Resolution during test (smaller than e): ………………………………………………….3) Application no. ΔLv = additional load with Ev 0 = error calculated at or near zero Reference position Tilted position with the limiting value of tilting Load. TILTING (A. ………………………………………… At start ………………………………………… Temp.5. h.
TARE (WEIGHING TEST) (A.: Type designation: Date: Observer: Verification scale interval. pres.: ………………………………………… Time: Bar./…. Ec ↑ ↓ ↑ mpe . I ΔL Load.: Rel. Indication.6.: ………………………………………… (only class I) At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add. ………………………………………… At start ………………………………………… Temp. L ↓ ↑ ↓ ↑ First tare load Second tare load Passed Error.1) Application no.OIML R 76-2: 2007 (E) 9 Report page …. …………………………………………………. load. h. E ↓ * * * * Check if |Ec| ≤ |mpe| Failed Remarks: 21 In operation Corrected error.4. e: Resolution during test (smaller than e): ………………………………………………….
Report page …./….
WARM-UP TIME (A.5.2)
scale interval, e:
Resolution during test
(smaller than e):
Rel. h.:
Bar. pres.:
(only class I)
Automatic zero-setting and zero-tracking device is:
Out of working range
Duration of disconnection before test:
E = I + ½ e – ΔL – L
E0 = error calculated prior to each measurement at or near zero (unloaded)
EL = error calculated at load (loaded)
Load, L
counted from the moment an indication has first appeared.
Check if |EL – E0| ≤ |mpe|
Add. load,
EL – E0
VOLTAGE VARIATIONS (A.5.4)
Mains power supply (AC), A.5.4.1
External or plug-in power supply device (AC or DC), A.5.4.2
Rechargeable battery power supply, (re)charge during the operation of the instrument is possible, A.5.4.2
Non-rechargeable and rechargeable battery power supply, (re)charge during the operation of the instrument is not
possible, A.5.4.3
12 V or 24 V road vehicle battery power supply, A.5.4.4
Unom =
Umin =
Calculate lower and upper limits of applied voltages according to A.5.4. If a voltage-range (Umin / Umax) is marked, use
the average value as reference value.
Category of power supply (if an instrument has more than one power supply): ...............................................................
Ec = E – E0 with E0 = error calculated at or near zero
error, Ec
10 e =
Category of power supply (if an instrument has more than one power supply): ..................................................................
Check if |Ec| ≤ |mpe|
AC mains voltage dips and short interruptions (B.3.1)
Power supply voltage for the test:
V = Unom or the average value of Umin and Umax
Check if a significant fault occurred
Duration / Number of Repetition
number of disturbances interval (s)
of Utest
Mains power supply voltage:
Indication, I
Significant fault (> e)
or detection and reaction
/….3. I Failed Remarks: 25 Yes (see remarks) . e: Resolution during test (smaller than e): ………………………………………………….2 Electrical bursts (B. 12. ………………………………………………….: ………………………………………… Time: Bar. N = neutral.: Rel. ………………………………………… ………………………………………… Temp.: Type designation: Date: Observer: Verification scale interval. pres.: ………………………………………… At start At max °C % hPa Mains power supply voltage: Unom V Power supply voltage for the test: Utest V = Unom or the average value of Umin and Umax Umin V At end V Umax Test voltage (bursts) on each connection of the mains power supply lines: 1 kV Duration of the test at connection and each polarity: 1 min Disturbance Result Bursts on connection Load L ↓ ground N ↓ ground PE ↓ ground Polarity No Without disturbance positive X negative Without disturbance positive X negative Without disturbance X positive negative L = phase.2) a) Mains power supply lines Application no. h.OIML R 76-2: 2007 (E) Report page …. PE = protective earth Check if a significant fault occurred Passed Significant fault (> e) or detection and reaction Indication.
OIML R 76-2: 2007 (E) b) Report page …. if necessary. I/O circuits and communication lines Application no./….: Type designation: Date: Observer: Verification scale interval. nature) Result Polarity/ disturbance Significant fault (> e) or detection and reaction Indication.: ………………………………………… At start At max At end °C % hPa Test voltage (bursts) on each cable/interface (I/O signals. data and control lines): 0.: ………………………………………… Time: Bar. …………………………………………………. Check if a significant fault occurred Passed Failed Remarks: 26 . ………………………………………… ………………………………………… Temp. e: Resolution during test (smaller than e): …………………………………………………. I No Yes (see remarks) Without disturbance 1 positive negative Without disturbance 2 positive negative Without disturbance 3 positive negative Without disturbance 4 positive negative Without disturbance 5 positive negative Without disturbance 6 positive negative Without disturbance 7 positive negative Without disturbance 8 positive negative Without disturbance 9 positive negative Explain or make a sketch indicating where the clamp is located on the cable.: Rel.5 kV Duration of the test at each cable/interface and each polarity: 1 min Disturbance Load Bursts on cable/interface (Type. pres. h. use additional page.
Date: ………………………………………… Observer: ………………………………………… Temp.OIML R 76-2: 2007 (E) Report page …. N = neutral. e: ………………………………………… Time: Resolution during test Bar.3) a) AC mains power supply Application no.: …………………………………………………. Type designation: …………………………………………………. h.: (smaller than e): Surges on AC mains power supply lines Load Disturbance 3 positive and 3 negative surges synchronously with AC supply voltage Polarity angle amplitude/ apply on 0° 90° 180° 270° Without disturbance 0.: Verification Rel. pres.: scale interval. PE = protective earth Check if a significant fault occurred Passed Remarks: Failed 27 At start At max At end °C % hPa Result Significant fault (> e) or detection and reaction Indication.5 kV pos X L ↓ N neg pos X neg pos X neg X pos neg Without disturbance 1 kV pos X neg pos X L ↓ PE neg pos X neg X pos neg Without disturbance 1 kV pos X neg pos X N ↓ PE neg pos X neg X pos neg L = phase.3 Surges (B. 12.3. I No Yes (see remarks) ./….
Any other kind of power supply Application no.OIML R 76-2: 2007 (E) b) Report page ….: Type designation: Date: Observer: Verification scale interval. I Significant fault (> e) or detection and reaction No Yes (see remarks) Without disturbance L ↓ N 0. PE = protective earth Check if a significant fault occurred Passed Failed Remarks: 28 . N = negative or neutral conductor.5 kV pos neg Without disturbance L ↓ PE 1 kV pos neg Without disturbance N ↓ PE 1 kV pos neg L = positive conductor . e: Resolution during test (smaller than e): ………………………………………………….: ………………………………………… Time: Bar. …………………………………………………. h./…. pres.: Rel.: ………………………………………… At start At max At end °C % hPa Kind or type of power supply DC Other form Voltage Surges on other power supply lines Disturbance Load Result 3 positive and 3 negative surges apply on amplitude Polarity Indication. ………………………………………… ………………………………………… Temp.
Check if a significant fault occurred Passed Failed Note: If the EUT fails. 6 8 (air discharges) pos.OIML R 76-2: 2007 (E) 12.: Rel. Remarks: 29 ./….4 Report page ….: Type designation: Date: Observer: Verification scale interval. ………………………………………… ………………………………………… Temp.: ………………………………………… Time: Bar. test points) Without disturbance 2 pos. …………………………………………………. 4 pos. 6 8 (air discharges) neg. pres.3. neg. Electrostatic discharges (B. e: Resolution during test (smaller than e): …………………………………………………. 4 neg. pos. h.4) a) Direct application Application no. I No Result Significant fault (> e) or detection and reaction Yes (remarks. Without disturbance 2 neg.: ………………………………………… Contact discharge At start At max At end °C % hPa Paint penetration Air discharges Discharges Load Test voltage (kV) Number of Repetition Polarity discharges interval ≥ 10 ≥ 10 s Indication. the test point at which this occurs shall be recorded.
the test point at which this occurs shall be recorded. 4 neg. I No Result Significant fault (> e) or detection and reaction Yes (remarks. e: Resolution during test (smaller than e): …………………………………………………. test points) Without disturbance 2 pos.: Type designation: Date: Observer: Verification scale interval. 6 pos.: ………………………………………… At start At max At end °C % hPa Horizontal coupling plane Discharges Load Test voltage (kV) Number of Repetition Polarity discharges interval ≥ 10 ≥ 10 s Indication. Indirect application (contact discharges only) Application no. h. Check if a significant fault occurred Passed Failed Note: If the EUT fails. test points) No Result Significant fault (> e) or detection and reaction Yes (remarks. 6 neg. Vertical coupling plane Discharges Load Test voltage (kV) Number of Repetition Polarity discharges interval ≥ 10 ≥ 10 s Indication.OIML R 76-2: 2007 (E) b) Report page …./….: ………………………………………… Time: Bar. 6 neg. 4 pos. …………………………………………………. ………………………………………… ………………………………………… Temp. 6 pos. 4 neg. I Without disturbance 2 pos.: Rel. Without disturbance 2 neg. Remarks: 30 . Without disturbance 2 neg. pres. 4 pos.
by photos or sketches a) Direct application Contact discharges: Air discharges: b) Indirect application 31 . Specification of test points of EUT (direct application).OIML R 76-2: 2007 (E) Report page …./…. e.g.
: ………………………………………… Time: Bar. ………………………………………… ………………………………………… Temp.6) Rate of sweep: Material of load: Disturbance Load Antenna Frequency Polarization range (MHz) Result Facing EUT Indication.3.3. I Without disturbance Front Vertical Right Left Rear Front Horizontal Right Left Rear Front Vertical Right Left Rear Front Horizontal Right Left Rear Frequency range: 26-2000 MHz or 80-2000 MHz Field strength: 10 V/m Modulation: 80 % AM. 1 kHz. ………………………………………………….: ………………………………………… At start At max At end °C % hPa Frequency range 26-2000 MHz if the test according to B. 12.OIML R 76-2: 2007 (E) 12. h. the frequency at which this occurs shall be recorded Check if a significant fault occurred Passed Failed Remarks: 32 Significant fault (> e) or detection and reaction No Yes (remarks) .: Type designation: Date: Observer: Verification scale interval.6 is performed (see form no.3.: Rel. pres.5 Report page …. sine wave Note: If EUT fails.6 cannot be applied (no mains or I/O ports available) Frequency range 80-2000 MHz if the test according to B.5) Application no. e: Resolution during test (smaller than e): …………………………………………………./…. Immunity to radiated electromagnetic fields (B.
e.g.OIML R 76-2: 2007 (E) Report page …./…. by photos or sketches: 33 . Description of the set-up of EUT.
………………………………………… ………………………………………… Temp. 1 kHz. e: Resolution during test (smaller than e): …………………………………………………. Immunity to conducted radio-frequency fields (B. pres.: Rel.15-80 MHz RF amplitude (50 ohms): 10 V (e. h. sine wave .: ………………………………………… At start At max At end °C % hPa Rate of sweep: Load: Cable / Interface Material of load: Frequency range (MHz) Indication.: ………………………………………… Time: Bar.6 Report page …./…. I No Result Significant fault (> e) or detection and reaction Yes (remarks) without disturbance without disturbance without disturbance without disturbance without disturbance without disturbance without disturbance without disturbance without disturbance without disturbance Frequency range: 0.3. ………………………………………………….) Check if a significant fault occurred.f.OIML R 76-2: 2007 (E) 12.m. the frequency at which this occurs shall be recorded Passed Failed Remarks: 34 Modulation: 80 % AM.6) Application no.: Type designation: Date: Observer: Verification scale interval. Note: If the EUT fails.
OIML R 76-2: 2007 (E) Report page …. e: Resolution during test (smaller than e): …………………………………………………./…. i.: Rel. h. I Significant fault (> e) or detection and reaction No Yes (remarks) Without disturbance 2a 2b* 3a 3b 4 * +50 V +20 V –200 V +200 V –16 V Test pulse 2b is only applicable if the measuring instrument may be connected to the battery via the main (ignition) switch of the car.: ………………………………………… 12 V battery voltage At start At max At end °C % hPa 24 V battery voltage 12 V battery voltage Disturbance Load Test pulse Conducted voltage Result Indication. if the manufacturer of the measuring instrument has not specified that the instrument is to be connected directly (or by its own main switch) to the battery. ………………………………………… ………………………………………… Temp.7) a) Conduction along supply lines of external 12 V and 24 V batteries Application no. 12.: Type designation: Date: Observer: Verification scale interval. pres.e. I Significant fault (> e) or detection and reaction No Yes (remarks) Without disturbance +50 V +10 V –150 V +100 V –7 V 2a 2b* 3a 3b 4 24 V battery voltage Disturbance Load Test pulse Conducted voltage Result Indication.3.: ………………………………………… Time: Bar. Check if a significant fault occurred Passed Failed Remarks: 35 .7 Electrical transients on instruments powered from a road vehicle power supply (B. ………………………………………………….
: ………………………………………… 12 V battery voltage At start At max At end °C % hPa 24 V battery voltage 12 V battery voltage Kind or type of other lines (no power supply lines) Disturbance Load Test pulse Result Conducted voltage Indication. pres.: Type designation: Date: Observer: Verification scale interval. ………………………………………… ………………………………………… Temp. I Significant fault (> e) or detection and reaction No Yes (remarks) Without disturbance a –60 V b +40 V Without disturbance a –60 V b +40 V Without disturbance a –60 V b +40 V 24 V battery voltage Kind or type of other lines (no power supply lines) Disturbance Load Test pulse Result Conducted voltage Indication. Capacitive and inductive coupling via lines other than supply lines Application no. Note: If EUT fails.: Rel. I Without disturbance a –80 V b +80 V Without disturbance a –80 V b +80 V Without disturbance a –80 V b +80 V Check if a significant fault occurred.: ………………………………………… Time: Bar. the frequency at which this occurs shall be recorded Passed Failed Remarks: 36 Significant fault (> e) or detection and reaction No Yes (remarks) . e: Resolution during test (smaller than e): …………………………………………………. ………………………………………………….OIML R 76-2: 2007 (E) b) Report page …. h./….
L Indication. load. Ec ↓ ↑ mpe . pres./….2) a) Initial test (at reference temperature) Application no.: ………………………………………… Time: Bar.: Type designation: Date: Observer: Verification scale interval. h.: ………………………………………… At start At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add. I ΔL ↓ ↑ ↓ ↑ * Error. 13 DAMP HEAT. STEADY STATE (B. E ↓ * Check if |Ec| ≤ |mpe| Passed Failed Remarks: 37 ↑ In operation Corrected error. Load.OIML R 76-2: 2007 (E) Report page ….: Rel. e: Resolution during test (smaller than e): …………………………………………………. ………………………………………… ………………………………………… Temp. ………………………………………………….
e: Resolution during test (smaller than e): ………………………………………………….: ………………………………………… At start At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add.: ………………………………………… Time: Bar. h. …………………………………………………. Load./…. Test at high temperature and 85 % relative humidity Application no. pres. Ec ↓ ↑ mpe . L Indication. E ↓ (*) ↑ In operation Corrected error. ………………………………………… ………………………………………… Temp.: Rel.OIML R 76-2: 2007 (E) b) Report page …. load. I ΔL ↓ ↑ ↓ ↑ * Check if |Ec| ≤ |mpe| Passed Failed Remarks: 38 Error.: Type designation: Date: Observer: Verification scale interval.
load.: Type designation: Date: Observer: Verification scale interval. E ↓ * Check if |Ec| ≤ |mpe| Passed Failed Remarks: 39 ↑ In operation Corrected error. I ΔL ↓ ↑ ↓ ↑ * Error. …………………………………………………./…. Load.OIML R 76-2: 2007 (E) c) Report page ….: ………………………………………… At start At max At end °C % hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add.: Rel.: ………………………………………… Time: Bar. pres. ………………………………………… ………………………………………… Temp. Final test (at reference temperature) Application no. L Indication. h. e: Resolution during test (smaller than e): …………………………………………………. Ec ↓ ↑ mpe .
OIML R 76-2: 2007 (E) 14 Report page …. IL ΔL0 Add.4) Application no.: °C % hPa Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. h.. load.1 e = If |(EL – E0)max – (EL – E0)min| ≤ 0. SPAN STABILITY (B. five loadings and readings shall be performed at each measurement. See remarks. pres. …………………… …………………… Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Zero load = Out of working range Test load = Automatic span adjustment device: Existent Non-existent At start Measurement no.1 e./…. …………………………………………………………………. Average error = average (EL – E0) = (EL – E0)max – (EL – E0)min = 0.: Rel.. pressure.: Type designation: Verification scale interval. load. e: Resolution during test (smaller than e): …………………………………………………………………. 1: Initial measurement Date: ………………………………………… Observer: ………………………………………… Location: ………………………………………… At max At end Temp. if not. etc. necessary corrections resulting from variations of temperature. Remarks: 40 . the loading and reading will be sufficient for each of the subsequent measurements. I0 EL = IL + ½ e – ΔL – L Add. ΔL EL EL – E0 Corrected value* 1 2 3 4 * 5 When applicable.: Time: Bar. Indication E0 of load.
I0 EL = IL + ½ e – ΔL – L Add. necessary corrections resulting from variations of temperature. pressure. Indication E0 of load.. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: 41 .: Time: Bar. load.: Rel. h... pressure.: °C % hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ……………………………………………………………………………………….: Rel. Indication E0 of load./…. load. 3: Date: Observer: Location: At start ………………………………………… ………………………………………… ………………………………………… At max At end °C % Temp. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. h. ΔL EL EL – E0 Corrected value* 1 2 3 4 * 5 When applicable.: Time: Bar.OIML R 76-2: 2007 (E) Report page …. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. load. See remarks. pres. pres. ΔL EL Corrected value* EL – E0 1 2 3 4 * 5 When applicable. etc. 2: Date: ………………………………………… Observer: ………………………………………… Location: ………………………………………… At start At max At end Temp. necessary corrections resulting from variations of temperature. IL ΔL0 Add. Subsequent measurements Measurement no. IL ΔL0 Add.: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ………………………………………………………………………………………. See remarks. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: Measurement no. I0 EL = IL + ½ e – ΔL – L Add. etc... load..
necessary corrections resulting from variations of temperature. Indication E0 of load.: Rel. See remarks.: Time: Bar. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero./…. See remarks. pres. etc. pres. load.OIML R 76-2: 2007 (E) Report page …. 4: Date: ………………………………………… Observer: ………………………………………… Location: ………………………………………… At start At max At end °C % Temp.. ΔL EL EL – E0 Corrected value* 1 2 3 4 * 5 When applicable.: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ………………………………………………………………………………………. I0 EL = IL + ½ e – ΔL – L Add. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: Measurement no. necessary corrections resulting from variations of temperature. I0 EL = IL + ½ e – ΔL – L Add. h. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. load. 5: Date: Observer: Location: At start ………………………………………… ………………………………………… ………………………………………… At max At end °C % Temp. ΔL EL Corrected value* EL – E0 1 2 3 4 * 5 When applicable.. etc. IL ΔL0 Add. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: 42 . Indication E0 of load. pressure. load. Subsequent measurements Measurement no..: Rel. h.: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ……………………………………………………………………………………….. pressure.. load.: Time: Bar.. IL ΔL0 Add.
IL ΔL0 Add. pres: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ………………………………………………………………………………………. I0 EL = IL + ½ e – ΔL – L Add.OIML R 76-2: 2007 (E) Report page …. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. Indication E0 of load. load. I0 EL = IL + ½ e – ΔL – L Add. Indication E0 of load../…. 6: Date: ………………………………………… Observer: ………………………………………… Location: ………………………………………… At start At max At end °C % Temp: Rel. ΔL EL EL – E0 Corrected value* 1 2 3 4 * 5 When applicable.. load. load. 7: Date: Observer: Location: At start ………………………………………… ………………………………………… ………………………………………… At max At end °C % Temp: Rel. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. ΔL EL Corrected value* EL – E0 1 2 3 4 * 5 When applicable. See remarks... If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: 43 . If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: Measurement no. See remarks. load. etc. IL ΔL0 Add.. pressure.. etc. pres: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ………………………………………………………………………………………. necessary corrections resulting from variations of temperature. h: Time: Bar. Subsequent measurements Measurement no. pressure. h: Time: Bar. necessary corrections resulting from variations of temperature.
pres. Indication E0 of load./…. : Date: Observer: Location: At start ………………………………………… ………………………………………… ………………………………………… At max At end °C % Temp.: °C % hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ……………………………………………………………………………………….: Rel.: Rel. IL ΔL0 Add. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: 44 . See remarks. Subsequent measurements Measurement no.: Time: Bar. IL ΔL0 Add.. If five loadings and readings have been performed: Average error = average (EL – E0) = Remarks: Measurement no. ΔL EL Corrected value* EL – E0 1 2 3 4 * 5 When applicable. load.. necessary corrections resulting from variations of temperature. pressure. load. pres. pressure..: hPa Measurement after the temperature test Measurement after the damp heat test Measurement after disconnection from the mains Measurement after change in test location Other condition: ………………………………………………………………………………………. h. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero. necessary corrections resulting from variations of temperature. h. …. Automatic span adjustment device activated (if existent) E0 = I0 + ½ e – ΔL0 – L0 Indication of zero... load. I0 EL = IL + ½ e – ΔL – L Add. etc. See remarks. Indication E0 of load. …. : Date: Observer: Location: At start ………………………………………… ………………………………………… ………………………………………… At max At end Temp. etc..OIML R 76-2: 2007 (E) Report page …. ΔL EL EL – E0 Corrected value* 1 2 3 4 * 5 When applicable. load. I0 EL = IL + ½ e – ΔL – L Add.: Time: Bar.
4) OIML R 76-2: 2007 (E) Report page …. damp heat test D and disconnections from the mains power supply P …………………………………………………………………………………………………………… Application no.Average error e 45 –1.5 e +1 e +1./…. .: 14 SPAN STABILITY (B.5 e 0 +0.5 e …………………………………………………………………………………………………………… Type designation: Passed 1 2 Failed 3 4 6 7 Maximum allowable variation 5 8 Measurement no. Plot on the diagram the indication of temperature test T .5 e –1 e –0.
Indication.6) Application no./…. …………………………………………………………………………………. load. L ↓ ↑ ↓ ↑ * Error.: Time: Bar. e: Resolution during test (smaller than e): …………………………………………………………………………………..OIML R 76-2: 2007 (E) 15 Report page ….: Type designation: Verification scale interval. I ΔL Load. ENDURANCE (A.: hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Add. pres. h.: Rel. E ↓ * 46 ↑ In operation Corrected error. Ec ↓ ↑ mpe . ………………………………………… a) Initial test Date: Observer: Location: ………………………………………… ………………………………………… ………………………………………… ………………………………………… At start At max At end °C % Temp..
load. Ec Error. I ΔL Load. E Failed Remarks: 47 ↑ ↓ ↑ mpe Durability error due to wear and tear** .: Rel.OIML R 76-2: 2007 (E) Report page ….: Time: Bar. L ↓ ↑ ↓ ↑ * ↓ * Check if the durability error due to wear and tear is ≤ mpe Passed Corrected error. b) Performance of the test Number of loadings: Load applied: At start c) Final test Date: Observer: Location: ………………………………………… ………………………………………… ………………………………………… At max At end °C % Temp. h. pres.: hPa Automatic zero-setting and zero-tracking device is: Non-existent Not in operation Out of working range In operation E = I + ½ e – ΔL – L Ec = E – E0 with E0 = error calculated at or near zero* Durability error due to wear and tear = |Ec initial – Ec final|** Add./…. Indication.
/….OIML R 76-2: 2007 (E) 16 Report page …. It may also include references to the manufacturer. EXAMINATION OF THE CONSTRUCTION OF THE INSTRUMENT Use this page to indicate any description or information pertaining to the instrument. Description: Remarks: 48 . additional to that already contained in this report and in the accompanying national type approval or OIML Certificate. a description of its main components. This may include a picture of the complete instrument. and any remark which could be useful for authorities responsible for the initial or subsequent verification of individual instruments built according to the type.
CHECKLIST This checklist has been developed based on the following principles:  to include requirements that cannot be tested according to tests 1 through 15 above.5.3).2 and 4.4). A cross in the box for “existent” indicates that the device exists and that it complies with the definition given in the terminology. a combined semi-automatic zerosetting and tare device operated by the same key (4. clause 6 of R 76-1 shall be followed in lieu of this checklist. if appropriate. or visually.3. 49 ./….  to include neither general requirements. and they shall not be considered as a substitution to these requirements. the descriptive markings (7.g. its type.9).13.1.2 and 3.1.  to include requirements which indicate prohibitions of some functions. the operating range of the tare device (4.g. e.g. When indicating that a device is non-existent.3]).OIML R 76-2: 2007 (E) Report page …. If appropriate. e. suitability for application. For non-mandatory devices. The requirements that are not included in this type evaluation report (tests 1-15 and checklist 17) are considered to be globally covered by the type approval or OIML Certificate (e. nor weights and verification devices.1. 4. The items on this checklist are provided to recall the requirements specified in R 76-1. e. the results stated in this checklist may be supplemented by remarks given on additional pages. classification criteria [3.g. This checklist is intended to serve as a summary of the results of examinations to be performed and not as a procedure.1.4). e. use and verification [4.1). automatic tare device for instruments for direct sales to the public (4. but that shall be checked experimentally.1.1.  not to include requirements that allow functions or devices to be used.1.1. also check the boxes to indicate that the tests are not applicable (see page 5).1. auxiliary verification devices (4. As for non-self-indicating instruments.6. e.g. suitability for use (4.2). e.g.g.3]. the checklist provides space to indicate whether or not the device exists and.
1.1.. Min and e of each load receptor on relating load measuring device (Lim and T = + if applicable) 50 Remarks .1./….1.1.5. e. T (subtractive tare only if T ≠ Max) maximum safe load.3 3.. Max2...OIML R 76-2: 2007 (E) 17 Report page ….………………………… Testing procedures 7.2 A..………………………… …………………………….2 G 7..1.1) 7.1 A. Max1..4 A. Max.. Compulsory if applicable: name or mark of manufacturer’s agent serial number identification marks on separate but associated units type approval mark scale interval.9. d (d < e) software identification (if applicable) maximum tare effect.1 A.1 All types of weighing instruments except non-self-indicating instruments (6.……. Min..1) (+3..2 4. Min verification scale interval. . e2.3...3 7. e and d (if d ≠ e) on or near display permanently shown in a clearly visible position possible to seal and apply a control mark/removal will result in destruction markings B and G additional information shown alternatively on a plate or displayed by a software solution either permanently or accessed by a simple manual command Instruments with several load receptors and load measuring devices: identification mark.3 A. / guarantees only .……. minimum capacity. Max.1. R 76-1) Descriptive markings Compulsory in all cases: manufacturer's mark or name accuracy class maximum capacity. to be used only as follows: special applications clearly marked (weighings ranges in classes I and II or II and III) near display “not to be used for direct sales to the public” (for instruments similar to those used for direct sales to the public) Presentation of markings: indelible easily readable grouped together in a clearly visible place Max.. e1. Lim (if Lim > Max + T) special temperature limits counting ratio ratio between weight platform and load platform range of plus/minus indication Additional markings: not to be used for direct sales to the public to be used exclusively for: the stamp does not guarantee .3 FAILED Requirement PASSED 17.4 and 7.1 B.: Type designation: ……………………………. CHECKLIST Application no.3. 7.15 7.1-6.3 (+3.3 7.1.
3 4.2.2.1 3. 3.2 A. 1-11) specific declaration of the manufacturer limiting value of tilting defined by the manufacturer Examination of: documents functions (spot checks) test reports from other authorities Indicating device Reading: reliable.6.5 4.1 8.1 A.2.1.3.1.4 a 4.1 4.5.2.1 A.2 3.2.2.1.1.2.2.1.1.4 b 4.3 7.2 4.10.10.1.2. shape and clarity by simple juxtaposition Units of: mass price 51 FAILED Requirement Report page ….2. stamping area ≥ 150 mm2 for self-adhesive type.1.4 c 4.1.9.10.1.2 e (analog indication) size. ø ≥ 15 mm Securing of components and preset controls: location form Securing with software means legal status of the instrument recognizable evidence of any intervention protection against changes of parameters and the reference numbers facilities for affixing the reference number Span adjustment device (automatic or semi-automatic): external influence impossible after securing Gravity compensation: external influence on or access to impossible after securing Documentation Technical information and data: characteristics of the instrument specifications of modules fractions. pi (modules tested separately) specifications of families specifications of components applicable descriptive documents (according to nos.2 4.1.Testing procedures 7.6 8.2.1 8.4 A.2.2.4 8.1 3.2 5.1.2 A.2.2 A.1 A.3 Separately-built main parts: identification mark repeated in descriptive markings Suitability for verification: identification of devices which have been subject to separate type examination Verification marks and sealing Verification mark: cannot be removed easy application visibility without the instrument to be moved when it is in service Verification mark support or space: which ensures conservation of the mark for stamp.3 4./….3 7. PASSED OIML R 76-2: 2007 (E) Remarks Existent Non-existent Existent Non-existent .1.4 4.2.1. easy and unambiguous overall inaccuracy ≤ 0.2.
4.2 4.3. data storage.4. signs or designations thereof weight values (not weighed) shall be clearly identified or display only temporarily on manual command and shall not be printed the inoperative weighing mode is clear and unambiguously recognizable 52 Remarks Non-existent Non-existent Non-existent . printing devices and tare weighing devices Form of digital indication: at least one figure at right Decimal sign: shall maintain its position (scale interval changed automatically) separate at least one figure to the left and all to the right on one line with the bottom of the figures Zero: only one non-significant zero to the right for values with decimal sign. 5 s after manual command prevention of printing while the device is in operation Digital indications other than primary indications: Existent additional indications do not lead to any ambiguity to primary indications quantities identified by units. PASSED OIML R 76-2: 2007 (E) Form of indication: for one indication.2 4. zero-setting. non-significant zero only in third position Limits: preventing of indication above Max + 9 e preventing of indication below zero unless a tare device is in operation (–20 d is accepted) “Approximate” displaying device: Existent scale interval > Max/100 without being smaller than 20 e Semi-self indicating instruments: extension of self-indication range ≤ self-indication capacity Analog indication: thickness and length of scale marks scale spacing limit of movement below zero and above capacity of selfindication damping of oscillations of displaying component Changing of digital indication: after change in load.1 4.3.4 4.3. or taring during continuous or temporary disturbance of equilibrium Extended digital indication: Existent not allowed when there is a differentiated scale division displaying a smaller scale interval only during pressing a key at most. symbols.3 4.3 4.4 Testing procedures FAILED Requirement Report page ….2.3.2 4.5 4. previous indication not longer than 1 s Stable equilibrium of digital indication: printed or stored weight values do not deviate more than 1 e from the final weight value zero or tare operations are within their accuracy requirements no printing.2.4 4.1 4.1 4.4.2.3 4.2.4.4. one unit of mass scale interval in the form (1./….2. 2 or 5) × 10k same scale interval for all indicating devices.2.2.
6.1 Non-existent differentiated scale division only to the right of decimal sign d < e ≤ 10 d. III or IIII a marking on the level indicator shows the limiting value of tilting level indicator fixed firmly in a place clearly visible to the user an automatic tilt sensor releases a display switch-off or other appropriate alarm signal and inhibits the printout and data transmission Zero-setting.3 Effect shall not alter Max Overall effect of: zero-setting zero-tracking initial zero-setting Accuracy: deviation ≤ 0.4. -tracking and -indicating 3.5 Digital printing: clear and permanent figures ≥ 2 mm high name or symbol of units to the right of the value above column of values printing impossible when equilibrium not stable Memory storage: storage.1 If existent.2 Remarks Existent Non-existent Initial zero-setting Automatic zero-setting Semi-automatic zero-setting Non automatic zero-setting Zero-tracking Zero-indicating 4.5.9.4. etc.3 3.1.2.4.6 3.4. transfer. totalizing. not allowed on multi-interval instruments) 4. inhibited when equilibrium not stable Auxiliary indicating device (Classes I and II only./….4 3.1 4.5.Testing procedures 4. e = 10k kg or e = 1 mg for class I with d < 1 mg Differences between results Differences: between multiple indications: ≤ mpe between digital indications and printout: zero between two results: ≤ mpe for same load when method of balancing changed (semi-self-indicating) Tilting of instrument of class II.3 4.2 4.4.1 A.2.5. PASSED OIML R 76-2: 2007 (E) Existent Non-existent Existent Non-existent Existent 3. type: rider interpolation complementary FAILED Requirement Report page ….4 A.25 e Multiple range: effective for greater weighing range (if switching when loaded possible) Control of zero-setting: separate from that of tare weighing device Semi-automatic zero-setting: functions only in stable equilibrium and if it cancels any previous tare operation 53 Existent = % = % Non-existent .5.4.6.
4 4.2 54 Existent Subtractive applicable requirements from 4.5.4. e = e1 for multi-interval better than ±0.Testing procedures 4. the overall effect may be 4 % of Max Tare devices Tare weighing Tare balancing Combined zero-setting and tare balancing Tare indicating Type: 4.1 through 4.5.5 d/s when operates after tare.2 4.6 4.8 4.4. “Net”.5.5.2 4.6.25 e (electronic instruments and instruments with analog indication).5.2.2) zero indicating device (4.4 are fulfilled Tare weighing device: dT = d Accuracy: ±0.25 e not mandatory if auxiliary indicating device or rate of zerotracking ≥ 0.3 4.6.6.5.5 A.6.7) FAILED Requirement Report page ….5 d (mechanical instruments with digital indication Operating range: prevention of operation at its zero effect or below its zero effect prevention of operation above its maximum indicated Visibility of operation: operation indicated net with sign “NET”.6./….6.6.7 Zero-indicating device (digital indication): shows deviation ≤ 0.6.5 4.5) zero-tracking (4.6.7 4.1 4.6.25 d/s Automatic zero-setting: operates only when equilibrium stable and indication has remained stable below zero at least 5 seconds Zero-tracking: operates only when indication at zero or at negative net value equivalent to gross zero and equilibrium stable corrections ≤ 0. “net” or complete word (digital indication) NET disappears if gross displayed temporarily tare value or letter “T” (mechanical additive tare device) Subtractive tare: prevention of use above Max or indication that capacity is reached Multiple range: operation effective in greater weighing ranges if switching when loaded possible tare values are rounded to the scale interval of the actual weighing range which is in operation Semi-automatic or automatic tare: operation only in stable equilibrium Combined zero/tare: accuracy (4. PASSED OIML R 76-2: 2007 (E) Remarks Non-existent Additive .6 4.9 A.
6.7.2 Existent Multiple ranges 4.10 Selection of weighing ranges: range in operation clearly indicated selection from smaller to greater range possible at any load (manual) selection from smaller to the following greater range (automatic) possible only for load ≥ Maxi of smaller range selection from a greater to a smaller range (manually) or to the smallest range (automatically) only  at no load when zero or negative net value is indicated  tare is cancelled automatically  zero is set to ±0.11.1 4.11 Printing net or gross: without designation designation: by G or B (gross) by N (only net printed) designation of net and tare by N and T (if net printed with gross and/or tare) instead of G. complete words printing separately net and tare with identification (determined by different tare devices) Existent Preset tare dT = d or automatically rounded to d 4.11.6.25 e1 automatically Selection between load receptors. shall be rounded to the latter (multiple range) tare value ≤ Max1 for the same net weight value (multiinterval) and calculated net value rounded to the scale interval for the same net weight value 4.5 4.Testing procedures FAILED Requirement Report page ….2 cannot be modified/cancelled if tare operated after the preset tare is still in use operates automatically if clearly identified with load 4.11.5 applies 4.7. B.11 applies designation of preset tare by PT or complete word Existent Locking devices 4.1 transferred from one range to another one with larger ei.1 Positions: only two stable positions weighing only in ‘weigh” position positions clearly shown 4.10 applies 4.6. N and T.10 55 Non-existent Non-existent Non-existent Non-existent .8. PASSED OIML R 76-2: 2007 (E) Consecutive tare operations: indicated or printed tare weight values clearly designated (if tare devices operative at the same time) 4. transmitting and measuring devices Existent compensation for unequal no-load effect 4./….3 weighing impossible while selection 4.6.7.6.2 zero-setting without ambiguity and in accordance with 4.11.3 possibility to indicate preset tare if calculated net printed then preset tare value is printed as well 4.4 combinations easy identifiable Remarks 4. 4.8.11.
2 4./….1 4.2 4.12 4. d = e on either side of zero and value of d = e shown at either end Mechanical counting instruments with unit weigh receptor Scale: with at least one scale division.12.17.17.12.20 Testing procedures “Plus and minus” comparator instruments Distinction of zones: “+” and “–” signs (analog indication) by inscription (digital indication) Scale: with at least one scale division.4. d = e on either side of zero and value of d = e shown on the scale Counting ratio: shown clearly above each counting platform or each counting scale mark Modes of operation: clearly identification of mode which is actually in operation manual switching back to weighing mode in any mode and at any time possible automatic selection of mode only within a weighing sequence automatic switching back to the weighing mode at the end of the weighing sequence zero indication after returning from switch-off condition automatic check of zero position before returning from switch-off condition 56 FAILED Requirement Report page ….1 4. PASSED OIML R 76-2: 2007 (E) Remarks .
OIML R 76-2: 2007 (E) Instruments for direct sales to the public and price computing and labeling instruments Requirement 4.5 mm Instruments to be used with weights: value of weights possible to distinguish Zero-setting device (direct sales to the public) Non-automatic zero-setting: only allowed when operated with a tool Tare device (direct sales to the public) not allowed on mechanical instrument with weights receptor on instruments with one platform public can see whether: .13.13.1.13.tare is in use .8. Testing procedures Remarks Miscellaneous checks (direct sales to the public) Combined semi-automatic zero-setting device and semi-automatic tare-balancing device operated by the same key: not allowed “Preweigh” position: not allowed Counting ratio: 1/10 or 1/100 (mechanical counting instrument) Impossibility of weighing during: locking operation adding or subtracting weights Auxiliary and extended indicating device: not allowed When significant fault has been detected 1 (electronic instruments): visible or audible alarm provided for customer and data transmission prevented until user takes action or cause disappears Indication device (direct sales to the public) Primary indications to both vendor and customer: two display sets.6 4. one vendor. 57 .tare setting is altered only one tare shall be in operation at any given time while tare or preset tare is in operation recalling of gross values is prohibited Non-automatic tare: displacement of 5 mm at most e Semi-automatic tare: reduction of value of tare not permitted and canceling of tare effect only if no load on the receptor One of the following condition fulfilled: tare value indicated permanently in a separate display Checked by verifying the compliance with documents or by simulating faults.5.and one customer display: Yes No one display set for vendor and customer Yes No weight information about correct zero position tare operation preset tare operation height of numerical figures displayed to the customer ≥ 9.13.3.2 1 PASSED FAILED 17.1-12.7. 4.7 4.13.13.13.2 4.9 4./….2 Report page ….13.3.3 4. this check does not duplicate the disturbance tests 12.13.5 4.1 4.10 4.13.4 4.1 4.
3 4. unit price and price to pay for nonweighed articles./….3 4.13.14 4.14.14.13.4 4.3 error of price scale |W × U – P| ≤ e × U Price computing: multiplication of indicated weight and unit price as indicated rounding to the nearest interval of price to pay unit price: price/100 g or price/kg Indications of weights.2 and 4.4.11 4.1 4.Requirement 4.3.13.13.6) unit price price to pay if applicable number.3.3.13 for direct sales to the public are met Supplementary primary indications (4.2 4. unit price and price to pay visible: while load on load receptor and for at least 1 s after stable weight indication or after any introduction of unit price freezing for ≤ 3 s after removing load and not possible to introduce or change unit price (if indication has been stable before and would otherwise be zero) printing weight.14. price totals Price scales: 4.14. PASSED FAILED OIML R 76-2: 2007 (E) Testing procedures indicated with sign “–” when no load on the receptor tare effect cancelled automatically when unloading after net weighing Automatic tare: not allowed Preset tare: indicated on separate display clearly differentiated from weight display reduction of tare value not permitted and canceling of tare effect only if no load on the receptor impossible to operate if tare device in operation cancelled at the same time as PLU if associated with PLU Self-service instruments: with one set of scales or displays two sets of scales or displays instrument has two sets of scales or displays Primary indications shall include the product designation if a ticket is printed Price computing instruments and price scales (direct sales to the public) Requirements of 4.1 Report page ….3 4.3. unit price and price to pay Stored in memory: before printing same data not to be printed twice for customer Additional functions for trade and management: all transactions are printed for customer they shall not lead to confusion Prices-to-pay (positive or negative) of non-weighed articles: weight indication zero or weighing mode inoperative prices shall be shown on price-to-pay display Prices for more than one equal articles: number of articles shown on weight display without being taken for a weight price for one article shown on unit price display 58 Remarks .1-4.4 4.2 4.3.1-4.14.
16 4.3 (paragraphs 1 and 5)./….Requirement 4.14.14.14. 4. PASSED FAILED OIML R 76-2: 2007 (E) Testing procedures Remarks supplementary display for number of articles and/or article prices Totalization of transactions on one or several tickets: price total indicated on price-to-pay display and printed accompanied by a special word or symbol and reference to commodities whose prices are totalized if a separate ticket is issued for total all prices-to-pay shall be printed and price total shall be the algebraic sum of these printed prices Totalization of transactions from linked instruments: price-to-pay scale intervals of all connected instruments identical Instrument used by several vendors or to serve more than one customer at the same time: connection between transactions and vendor or customer identified Canceling previous transactions: transaction is already printed: the price-to-pay cancelled shall be printed with comment transaction not yet printed and displayed to customer: transaction clearly differentiated from normal transactions Printing additional information: clearly correlated to transaction and does not interfere with assignment of weight value to unit symbol Price labeling instruments requirements 4.4 4.14.4. 4.4.4.2 4.14.18.5 4.4.2 Report page ….13.14.8.4.14. unit price and price-to-pay allowed provided weighing mode is inoperative Mobile instruments used outside means to indicate that the limiting value of tilting has been exceeded and to inhibit printout and data transmission automatic zero-setting or tare balancing operation after each moving of the vehicle Weighing window Existent Non-existent indication when instrument is not in the weighing window and the printout and data transmission is inhibited equipped with an appropriate protection system if the load measuring device is sensitive to moving or driving influences prevention of wrong weighing results if the cardanic suspension system or load receptor comes into contact with the surrounding frame construction Other mobile instruments not to be used outside with a leveling device and a level indicator the leveling device shall be operated easily without tools appropriate inscription pointing the user to the necessity of leveling after each movement 59 .4.3 4.1 (paragraph 1) and 4.18.5 are met Display: for weight possibility to verify values of unit price and preset tare during the use of the instrument Printing: prevention of printing below Min labels with fixed values of weight.1 4.
1 can be secured interfaces transmit data so that peripheral device can meet requirements metrologically relevant functions performed or initiated through the interface meet relevant requirements of R 76-1 Checked by verifying the compliance with documents or by simulating faults. or visual or audible indication until user takes action or fault disappears1 Display check Upon switch-on: signs of indication are active and non-active long enough to be checked by operator External equipment Interfaces (mechanical.3.1. logical) do not allow:  functions and measurement data to be inadmissibly influenced by peripheral devices.1 b): instrument made automatically inoperative 1.3. Testing procedures Remarks Disturbances indication of significant faults in the display does not lead to confusion with other messages Acting upon significant faults in case 5.3 5. processed.OIML R 76-2: 2007 (E) Electronic weighing instruments Requirement 5.1-12.1 5.6.1 5. stored)  changing adjustment factor or adjusting the instrument (except authorized cases)  falsifying displayed primary indications (direct sales) interfaces that do not fulfill 5.3.6 5.3.2 5.2 5. electrical./…. this check does not duplicate the disturbance tests 12.7. or disturbances  displaying data which could be mistaken for a weighing result  falsifying weighing results (displayed.6.3. or other connected instruments.6 1 PASSED FAILED 17.6.3.3 Report page ….1 5.3.1. 60 .6.
2 device-specific parameters sufficiently protected audit trail for the protection of the parameters and description some practical spot checks performed 5.1 or G.OIML R 76-2: 2007 (E) Software-controlled digital devices and instruments Requirement PASSED FAILED 17. Non-existent and elements with programmable or loadable legally relevant software Existent the legally relevant software is: 5.2 b G.3 In addition to the cases G.2.2 a verification / inspection 5.2.2 d G.2.5. the legally relevant software part:  is separated from associated software  identified  cannot be influenced by the associated software program modules of legally relevant software are defined and separated from the modules of associated software by a defined protective software interface protective software interface itself is part of the legally relevant software description and definition of functions of the legally relevant software that can be released via the protective software interface description and definition of parameters that may be exchanged via the protective software interface 61 .1  documented with all relevant information  protected against accidental or intentional changes 5. devices.1  is used in a fixed hardware and software environment.2.2 G.2.2.1 Operation system / programs not accessible for the user description of all commands via keys or interfaces declaration of completeness of commands 5.5.2.2.2.2. instruments with PC components.5. and  cannot be modified or uploaded by any means after securing/ verification the software documentation contains:  description of the legally relevant functions  description of the securing means (evidence of an intervention)  software identification  description how to check the actual software identification the software identification is:  clearly assigned to the legally relevant software and functions  provided by the instrument as documented Existent Remarks Non-existent Personal computers.5.2 Operating system / programs accessible for the user checksum or signature generated over the machine code of the legally relevant software legally relevant software cannot be started if the code is falsified G.2. modules.4 Report page ….2.5.2.2.5.1 G.3 Software interfaces if there is associated software providing other than measuring functions.2.2.5. Testing procedures Devices with embedded software declaration of the manufacturer that the software: 5.2 a evidence of intervention is available until the next 5.2./….2.2 G. and other instruments.
3. i.3.3.5 data with an identification number record of the identification number on the official transaction medium.3.5.5 G.6 G. tare values.5.e. i. instrument number.5. identifications of the data set. PASSED FAILED OIML R 76-2: 2007 (E) Testing procedures description of the functions and parameters conclusive and complete each documented function and parameter does not contradict with the requirements of this Recommendation appropriate instructions for the application programmer concerning the protectiveness of the software interface 5.1) protection of the stored legally relevant data by an adequate checksum or of a storage device with programmable or loadable software (5.3.3. on the print-out automatic storage of the legally relevant data 5. to G.3.6 a device subject to legal control prints or displays the stored 5. (if applicable).5.2 data are stored and given back correctly sufficient description of measures to prevent data loss storage of all relevant information necessary to reconstruct an 5.3 G.1) 5.1) documentation with all relevant information sufficient storage capacity for the intended purpose 5.5.1 G.3 earlier weighing.2 G.3.4 Software identification the legally relevant software is identified by a software identification the software identification:  covers all program modules of the legally relevant software and the type-specific parameters at runtime of the instrument  is easily provided by the instrument  can be compared with the reference identification fixed at type approval spot checks whether the checksums (signatures) are generated and work as documented there exists an effective audit trail Data storage devices (DSD) Existent DSD realized with embedded software (examine software acc.3.5.3. checksum / signature of the data set stored protection of the stored legally relevant data against 5.2 c G. to G.3.e.5.5.4 accidental or intentional changes protection of the stored legally relevant data at least with a parity check during transmission to the storage device protection of the stored legally relevant data at least with a parity check of a storage device with embedded software (5. decimal signs./…. net. units.3.3.2) identification and indication of the stored legally relevant 5.7 legally relevant data for verifying 62 Remarks Non-existent Yes No Yes No . gross.2.5.2.3 G.Requirement Report page …. load receptor.5.1 DSD realized with programmable/loadable software (examine software acc.4 G.
Documents Similar To OIML R 76-2
Lily Yanti Ramli
Ld1916k(Ru) Service Manual m7c1v2.00,m7c2v2.00
DX100 Maintence
Aritech Fp 408 User guide. Fire Alarm
More From Francisco Leal
Decreto 1595 Del 05 de Agosto de 2015 (1)
reglamento_tecnico_especiales
Ensayo REMODELACIÓN DE LUMINARIAS DEL ESCENARIO DEPORTIVO COLISEO MAYOR RAFAEL CUARTAS GAVIRIA
Análisis sentencia 41-001-23-31-000-2000-02956-01 consejo de estado
Manual de Uso Facil GSC59
An Electrode Shape Configuration on the Performance of Die Sinking Electric Discharge Machine (EDM): A Review
ME 303 Assignment
Life Extension Technique of Welded Structure using HFMI/PIT: A Review on Past and Current Researches with Applications
WELD_FITTING_SPECS.pdf
Towards a Unified Physics: What is Gravity?
Full Vehicle NVH Analysis with Rolling Tires 2011