BS PD CEN TR 15500-2-2016 Energy Performance of Buildings Control for heating ventilating and air-conditioning applications Accompanying TR prEN 15500-1 2015 Modules M3-5 .pdf

1、PD CEN/TR 15500-2:2016 Energy Performance of Buildings Control for heating, ventilating and air- conditioning applications Part 2: Accompanying TR prEN 15500-1:2015 - Modules M3-5, M4-5,M5-5 BSI Standards Publication WB11885_BSI_StandardCovs_2013_AW.indd 1 15/05/2013 15:06PD CEN/TR 15500-2:2016 PUBL

2、ISHED DOCUMENT National foreword This Published Document is the UK implementation of CEN/TR 15500-2:2016. The UK participation in its preparation was entrusted to Technical Committee RHE/16, Performance requirements for control systems. A list of organizations represented on this committee can be ob

3、tained on request to its secretary. This publication does not purport to include all the necessary provisions of a contract. Users are responsible for its correct application. The British Standards Institution 2016. Published by BSI Standards Limited 2016 ISBN 978 0 580 92591 7 ICS 91.140.30; 97.120

4、 Compliance with a British Standard cannot confer immunity from legal obligations. This British Standard was published under the authority of the Standards Policy and Strategy Committee on 31 August 2016. Amendments/corrigenda issued since publication Date T e x t a f f e c t e dPD CEN/TR 15500-2:20

5、16TECHNICAL REPORT RAPPORT TECHNIQUE TECHNISCHER BERICHT CEN/TR 15500-2 August 2016 ICS 97.120; 91.140.30 English Version Energy Performance of Buildings - Control for heating, ventilating and air-conditioning applications - Part 2: Accompanying TR prEN 15500-1:2015 - Modules M3- 5,M4-5,M5-5 Begleit

6、ender TR zu EN 15500 This Technical Report was approved by CEN on 11 April 2016. It has been drawn up by the Technical Committee CEN/TC 247. CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republ

7、ic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom. EUROPEAN COMMITTEE FOR STANDARDIZATION COMIT EUROPEN DE NORMALI

8、SATION EUROPISCHES KOMITEE FR NORMUNG CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels 2016 CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Members. Ref. No. CEN/TR 15500-2:2016 EPD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 2 Contents

9、 Page European foreword . 4 Introduction 5 1 Scope 7 2 Normative references 7 3 Terms and definitions . 8 4 Symbols and abbreviations . 8 4.1 Symbols . 8 4.2 Abbreviations . 8 5 Functional and acceptance test 8 5.1 Objective of the Test methodology . 8 5.2 Testing procedures Test principle 8 5.3 Tes

10、t parameters. 9 5.3.1 Temperature parameters 9 5.3.2 Time parameters 10 5.3.3 Product configuration 10 6 Definition of Control Accuracy (CA), Control Variation (CV) and Control to Setpoint Deviation (CSD) . 11 6.1 General . 11 6.2 Definition of the Control Accuracy for heating (CA H) 12 6.3 Definiti

11、on of the Control Accuracy for cooling (CAC) 13 6.4 Definition of CV and CSD 13 7 Test facility description General layout . 13 8 Sensor side interface . 15 8.1 General . 15 8.2 Temperature interface for the controller . 15 8.2.1 Option 1 - Sensor resistance simulator 15 8.2.2 Option 2 - Climatic bo

12、x . 16 8.3 Pressure interface for the controller (VAV application) . 17 8.3.1 General . 17 8.3.2 Pressure generator 17 8.3.3 Voltage signal . 18 8.4 Actuator side interface . 18 8.4.1 General . 18 8.4.2 Interface for real valve/drive combinations 19 8.4.3 Interface for other outputs . 20 8.5 Interfa

13、ce between real and simulated environment. 20 8.5.1 General . 20 8.5.2 Link from simulated to real environment . 21 8.5.3 Link from real to simulated environment . 21 8.6 Simulated environment . 21 8.7 Data acquisition system . 21 8.7.1 Function . 21 8.7.2 Specifications . 21 PD CEN/TR 15500-2:2016

14、CEN/TR 15500-2:2016 (E) 3 Annex A (informative) Data . 22 A.1 Objective 22 A.2 Applications 22 A.3 Building and zone types . 22 A.3.1 Building types 22 A.3.2 Zone types . 23 A.4 Default time test parameters . 23 Bibliography . 24 PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 4 European foreword Thi

15、s document (CEN/TR 15500-2:2016) has been prepared by Technical Committee CEN/TC 247 “Building Automation, Controls and Building Management”, the secretariat of which is held by SNV. Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights.

16、 CEN shall not be held responsible for identifying any or all such patent rights. This document has been prepared under a mandate given to CEN by the European Commission and the European Free Trade Association. This document is currently divided into the following parts: Control for heating, ventila

17、ting and air-conditioning applications Part 1: Electronic individual zone control equipment Modules M3-5,M4-5,M5-5 currently at Enquiry stage; Control for heating, ventilating and air-conditioning applications Part 2: Accompanying prEN 15500-1:2016 Modules M3-5,M4-5,M5-5 the present Technical Report

18、; currently at Voting stage. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 5 Introduction The CENSE project, the discussions between CEN and the Concerted action highlighted the high page count of the entire package due to a lot of “textbook” information. This resulted in flooding and confusing the

19、 normative text. A huge amount of informative contents shall indeed be recorded and available for users to properly understand, apply and nationally adapt the EPB standards. The detailed technical rules CEN/TS 16629 Detailed Technical Rules ask for a clear separation between normative and informativ

20、e contents: to avoid flooding and confusing the actual normative part with informative content; to reduce the page count of the actual standard; to facilitate understanding of the package. Therefore each EPB standard shall be accompanied by an informative technical report, like this one, where all i

21、nformative contents is collected. Table 1 shows the relative position of this TR within the EN EPB set of standards. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 6 Table 1 Position of this TR within the EPBD set of standards Over- arching Building (as such) Technical Building System Descriptions D

22、escriptions Descriptions Heating Cooling Ventilation Humidification Dehumidification Domestic Hot waters Lighting Building automation and control PV, wind, M1 M2 M3 M4 M5 M6 M7 M8 M9 M10 M11 General General General Common terms and definitions; symbols, units and subscripts Building Energy Needs Nee

23、ds Application (Free) Indoor Conditions without Systems Maximum Load and Power Ways to Express Energy Performance Ways to Express Energy Performance Ways to Express Energy Performance Building Functions and Building Boundaries Heat Transfer by Transmission Emission and control x x x Building Occupan

24、cy and Operating Conditions Heat Transfer by Infiltration and Ventilation Distribution and control Aggregation of Energy Services and Energy Carriers Internal Heat Gains Storage and control Building Partitioning Solar Heat Gains Generation and control Calculated Energy Performance Building Dynamics

25、(thermal mass) Load dispatching and operating conditions PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 7 Over- arching Building (as such) Technical Building System Descriptions Descriptions Descriptions Heating Cooling Ventilation Humidification Dehumidification Domestic Hot waters Lighting Buildin

26、g automation and control PV, wind, M1 M2 M3 M4 M5 M6 M7 M8 M9 M10 M11 Measured Energy Performance Measured Energy Performance Measured Energy Performance Inspection Inspection Inspection Ways to Express Indoor Comfort BMS External Environment Conditions Economic Calculation 1 Scope This Technical Re

27、port refers to prEN 15500-1, Control for heating, ventilating and air-conditioning applications Part 1: Electronic individual zone control equipment Modules M3-5,M4-5,M5-5. It contains information to support the correct understanding, use and national adaption of prEN 15500-1:2016. This Technical Re

28、port does not contain any normative provision. 2 Normative references The following documents, in whole or in part, are normatively referenced in this document and are indispensable for its application. For dated references, only the edition cited applies. For undated references, the latest edition

29、of the referenced document (including any amendments) applies. prEN 15500-1:2016, Control for heating, ventilating and air-conditioning applications Part 1: Electronic individual zone control equipment Modules M3-5,M4-5,M5-5 EN ISO 7345:1995, Thermal insulation - Physical quantities and definitions

30、(ISO 7345:1987) prEN ISO 52000-1:2016, Energy performance of buildings Overarching EPB assessment Part 1: General framework and procedures (ISO/DIS 52000-1:2015) PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 8 3 Terms and definitions For the purposes of this document, the terms and definitions give

31、n in EN ISO 7345:1995, prEN ISO 52000-1:2016 and prEN 15500-1:2016 (the accompanied EPB standard) apply. 4 Symbols and abbreviations 4.1 Symbols For the purposes of this Technical Report, the symbols given in prEN ISO 52000-1:2016 and prEN 15500-1:2016 (the accompanied EPB standard) apply. 4.2 Abbre

32、viations For the purposes of this Technical Report, the abbreviations given in prEN ISO 52000-1:2016 and prEN 15500-1:2016 (the accompanied EPB standard) apply. 5 Functional and acceptance test 5.1 Objective of the Test methodology This section provides a test method for the compliance of controller

33、s with the specified control accuracy in EN 15500-1:2016, 5.4. For the facility of the reader, these definitions will be duplicated in this Technical Report. This consists of the following elements: testing procedures; test facilities description: gives a description of the different equipment perta

34、ining to the bench, their functions, requirements and specifications; description of the simulator: gives details about the simulator framework, user interfaces, models layout and the running of the tests. The time parameters for the test procedures are given in the informative Annex A. 5.2 Testing

35、procedures Test principle This standard covers the test of a terminal control loop as shown in Figure 1. The temperature in the room is measured by the temperature sensor of a controller which commands then the HVAC terminal system in the room, via an actuator e.g. actuator/valve combination for wat

36、er systems. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 9 Figure 1 Example for Control loop for HVAC terminal systems The test of this controller is carried out by emulation technique in transient state and the real controller to be tested is implemented in a simulated environment with the room (

37、dynamic model of the heat and mass transfer) and the HVAC system (Figure 1). The room temperature is finally used to assess the performance of the controller. In this approach, the sensor as well as the actuator can be real or simulated. The test procedures and parameters are described in the follow

38、ing sections. 5.3 Test parameters 5.3.1 Temperature parameters Tests are conducted by simulating three periods of 20 %, 50 % and 80 % load conditions for HVAC emitter during heating and cooling tests. The variation of the internal gains in the zone presents also three periods: 0 %, 30 % and 60 % of

39、the load. Following these variations of the load and internal gains, six periods are defined: PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 10 Table 2 Definition of the variable test parameters Period Thermal state of the zone Internal gain Heating load Cooling load P1 overshoot 0 % 80 % 20 % P2 tr

40、ansient P3 overshoot 30 % 50 % 50 % P4 transient P5 overshoot 60 % 20 % 80 % P6 transient Tests are performed with the fixed parameters described in Table 3. Table 3 Fixed test parameters and room temperature setpoint Parameter Heating Cooling Temperature setpoint 20 C 24 C Initial zone temperature

41、20 C 24 C Outdoor temperature 4 C 30 C 5.3.2 Time parameters The test is split into 6 periods to evaluate the zone controllers performance at three load conditions, when the controller output is in the process of stabilizing (following a change in load condition) and when the output is considered st

42、able (after time period T1) as shown in next table. The period T1 is defined in order to avoid the overshoot of the controller. The period T2 is defined in order to qualify the performance of the controller associated to a transient state of the building (zone) thermal behaviour (Table 4). Table 4 P

43、eriod of tests Period Internal gains Heating load Cooling load Start time Finish time P1 0 % gain - overshoot 80 % 20 % 0 T1 P2 0 % gain - transient state T1 T2 P3 30 % - overshoot 50 % 50 % T2 T2 + T1 P4 30 % gain - transient state T2 + T1 2 T2 P5 60 % gain - overshoot 20 % 80 % 2 T2 2 T2+ T1 P6 60

44、 % gain - transient 2 T2 + T1 3 T2 5.3.3 Product configuration The temperature of the setpoint shall be programmed in accordance with 5.3. The program shall be in the mode for not intermittent occupancy. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 11 Key a) not intermittent b) intermittent Figure

45、 2 Product configuration 6 Definition of Control Accuracy (CA), Control Variation (CV) and Control to Setpoint Deviation (CSD) 6.1 General The Control Accuracy (CA), Control Accuracy for Heating (CA H), Control Accuracy for Colling (CA C), Control Variation (CV) and Control to Setpoint Deviation (CS

46、D) are defined in prEN 15500-1:2016. The definitions for CA H and CA C take into account the behaviour of the user as detailed in Subclauses 6.2 and 6.3. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 12 6.2 Definition of the Control Accuracy for heating (CA H) Key temperature t Time z,set setpoint

47、zone temperature CR comfort region 1, 2, 3, 4 Number of the four considered cases Figure 3 Control Accuracy for heating (CA H) In the first case CSD -CV 0, the user will shift the setpoint upwards in order to avoid that there are zone temperatures below the comfort region CR. In consequence, the ave

48、rage room temperature will be CV higher than the original setpoint, i.e. the lower limit of the comfort region CR. Regarding the energy consumption we get that the control accuracy CA H is equal to CV. For the others cases, the approach is analogous. PD CEN/TR 15500-2:2016 CEN/TR 15500-2:2016 (E) 13

49、 6.3 Definition of the Control Accuracy for cooling (CAC) Key temperature t Time z,set setpoint zone temperature CR comfort region Figure 4 Control Accuracy for cooling (CA C) In case of cooling, the approach is similar to heating. 6.4 Definition of CV and CSD Control Variation (CV) and Control to Setpoint Deviation (CSD) are defined in prEN 15500-1:2016. 7 Test facility description General layout The test principle relies on the testing of a real controller against a set of exam