The revised Lighting Guide 2, CIBSE’s long-awaited update of its publication on lighting for hospitals and healthcare buildings, has finally arrived. In many ways it has benefited from the delay – for example we took the opportunity to harmonise its content and task illumination levels with the requirements of BS EN 12464-1: Light and lighting. Lighting of work places; Part 1: Indoor work place. And it better reflects the way hospitals are built these days and, more importantly, the way they are run. While paying respect to the technical content of the 1989 edition, the guide encourages lighting designers to take a more holistic approach to their profession.

Understandably, publications aimed at advising lighting designers, especially within the healthcare establishment, have generally focused on technical requirement; but lighting has always been about more than just providing for the visual task – it has to be about the illumination of spaces, enhancing and describing the architecture, and it must be a producer of emotion. So while centring on the specific task requirements, the guide also pushes the designer to think about the balance of the three-dimensional space by considering vertical surface luminance, spatial colour and the architectural intent. It encourages lighting that is not only functional but mirrors the efficiency and drama of similar areas in large commercial buildings to create pleasurable spaces.

The irony of previous publications is that they are aimed at a sector that is self-governed – formerly by the NHS, now by the Department of Health (DoH) – which also produces its own technical guidance for use by its staff and to act as advisory documentation for private design consortiums. Avoiding contradictions Unfortunately, in the past some of the advice given by both parties has been slightly contradictory and a source of confusion. LG2 2008 set out to resolve this by inviting the DoH onto the task group to contribute in formulating the guidance. Its involvement has formally endorsed LG2 as an authoritative document. One of its major concerns was the guide’s ability to encourage energy savings and make this become a major consideration in the lighting design process. The government is forcing the DoH to find ways to reduce its energy use, but despite its efforts it is still seeing large annual increases in consumption and energy costs are starting to soak up a significant part of the annual budget.

Cibse Lighting Guide Pdf

It is now a statutory obligation for any lighting scheme proposed within England and Wales to meet the requirements of the Building Regulations Approved Documents L1 and L2 on the conservation of fuel and power. These were mainly introduced to discourage the use of inefficient light sources and do nothing to promote a more thoughtful design process rewarded by further energy savings. In response to requests from the Department of Health to look at ways to help reduce its energy needs, LG2 details a new design energy efficiency rating system (DEER) aimed at encouraging responsible lighting design (see sample worksheet below). It largely follows the principles of Part L but uses its target value as a base level or statutory minimum. It then extends the scheme by introducing two higher levels of efficiency, best practice and exemplary. The three levels and the corresponding energy target values are:. DEER level C (statutory minimum): 45–59 luminaire lumens per circuit watt inclusive.

DEER level B (best practice): 60–65 luminaire lumens per circuit watt inclusive. DEER level A (exemplary): 66 and above luminaire lumens per circuit watt. The DEER method rewards greater attention to detail during the design process but still allows for visual expression. It also allows the specification of a project to be centred on energy efficiency if required. Lighting designers and specifiers should be aware that the system is partially “aspirational”, in that it will require lighting application and luminaires to be developed before it’s possible to constantly achieve the highest levels set. So at present, while it may not be possible to achieve an “overall” exemplary level in every case, it should be possible to achieve it within certain areas, so the task should be to identify and set achievable targets while encouraging maximum energy savings.

The DEER method can be used on small or major projects, but for it to be effective it should adequately cover most areas of a building, which in the case of a new hospital are extensive. However a lot of areas are duplicated, so LG2 defines 10 such common areas covering everything from offices to operating theatres and corridors. Obviously if the project is smaller in scale then only the areas immediately concerned with the project need to be considered. In fact the specification can concentrate one particular area and request a certain level be met within that area if important. Further examples of the publication’s efforts to increase energy efficiency can be seen in the lighting schedule.

It goes on to promote the principle of energy saving by introducing a maximum value for each task area, a move that is aimed at encouraging the use of lighting controls. Optimum heights One change introduced in the guide is the recommendation that wall-mounted luminaires used for general or patient care lighting be mounted at a minimum of 1.8m from finished floor level to the physical centre of the luminaire.

This is deemed the optimum height to provide greater efficiency, especially for the indirect component by virtue of its reduced task to source distance, and its proximity will also aid visual comfort. If the optimum mounting height cannot be achieved the designer should ensure that any visual discomfort to patients and staff, especially those arising from views of the indirect source, is kept to a minimum. If the indirect component is to be mounted lower than 1.8m then the luminance limiting value of 1500cd/m2 (average) between the elevation angles of 90º and 145º should be achieved.

On the subject of patient lighting, the guide redefines the task lighting requirement for reading and other such tasks by introducing a “patient reading/activity plane”. Previous editions have called for the patient’s reading light to give a minimum of 300 lux on and around the pillow area; in reality most people will rest with their head or back against the pillows, so the actual task area requiring illumination will be further down the bed, probably around the region of the patient’s torso.

For this reason, and to allow for the various positions adopted by the patient at rest, the 300 lux value should be an average value measurable over a horizontal area of 1m × 1m (ie 1m2) centred at the bed head and directed towards the bottom of the bed at a working height of 1m above floor level. It is also a common practice in wards that during periods of rest the indirect or room lighting component will be switched off to aid sleep; any patient wishing to read during these times will use their personal reading light. It is therefore imperative the designer ensures that any luminaire intended to be used as a patient reading light fully meets the performance requirements detailed above independently of any indirect or room lighting component; the calculation or demonstration should also show that it has taken into account the possible shielding effect of the bedhead or the patient’s head and shoulders. The guide continually advocates the need for the designer to create comfortable lighting conditions, especially within the wards. Quality and comfort of the lit space when viewed by the recumbent patient will be greatly dependant on controlling the direct glare from the luminaires and the luminance balance it produces on the room’s surface. In order to ensure the quality of the lit environment is achieved, LG2 now requires a multiple level assessment to be carried out. The direct glare from the luminaire together with its average luminance against its immediate background should be calculated, followed by the luminance balance produced on the room’s surfaces by the luminaires.

All the calculations can be easily undertaken using most of the lighting calculation software programs currently available. Nurse, the screens One other criterion must also be demonstrated, namely the illumination values on the bed with the privacy curtains closed, compared with the illumination values when they are open. When patients are being attended to by nursing or medical staff, curtains will usually be pulled around the bed to provide an element of privacy.

The lighting design must demonstrate that in these circumstances, the average illuminance within the curtained area for both the general level and the nursing care level must not be reduced by more than 25% when compared with the unscreened bedded area; ie the minimum recorded average illuminance must not be less than an average of 75 lux for the general lighting level and not less than an average of 225 lux for the nursing care level. The calculation should also prove that the minimum acceptable illumination level of 75 lux (average) for the general ward lighting is maintained outside the bedded area when all the bed curtains within the ward are drawn around simultaneously. One other important area where LG2 2008 differs from previous editions is in the design and provision of night lighting. Night lighting needs to achieve two things: first, to provide enough light for the safe movement around the general ward area; and second, to allow the nursing staff the ability to discern facial features and a patient’s general condition. A patient in discomfort will generally convey this through facial or arm gestures.

It is important therefore that the lighting level is sufficient to allow staff on nightly rounds to see the patient’s face, but not high enough to destroy a good sleeping environment. The illuminance for the central ward circulation space should be no more than 5 lux average at 0.85m working plane. In addition the maximum permissible level measured anywhere on the pillow should be 0.5 lux. To help with visual acuity the maximum level measured anywhere in the ward should not exceed 10 lux at a working plane of 0.85m.

At this level, visual acuity is very low but it is still possible to discern the movement of patients. The use of a single source to illuminate the whole room will not achieve the performance criteria and should now be avoided; LG2 2008 recommends the use of multi-lamp or localised sources. Low output devices such as light emitting diodes (LEDs) may prove a better choice for night lighting applications against the use of dimmed or low wattage fluorescent lamps.

Night lighting needs to be considered as part of the whole design and not as an afterthought or a totally separate provision.

Recessed lighting guideGuide

The way designers approach emergency lighting changed fundamentally last year, with the extensive revision of BS 5266 Emergency lighting – Part 1: Code of practice for the emergency lighting of premises. The standard has more on emergency safety lighting and standby lighting, and responsibilities are better defined – but the area is now more complex, so there is potential for misunderstandings between the parties responsible for the briefing, design, installation, testing/commissioning and ongoing operation of emergency lighting. Emergency lighting is required for incidents involving a power failure – where the absence of electric light would compromise people’s means of escape – and ensures the safety of building occupants, including in external areas, up to the place of safety as defined by BS EN 1838. It is governed by a number of documents. The ultimate legal statutes are: the Regulatory Reform (Fire Safety) Order; the Health and Safety at Work Act; Building Regulations; and the EU Workplace Directive. Specific compliance guidance is given by Approved Documents B1 and B2, and design and product standards BSs and BS ENs as identified below: The Society of Light and Lighting’s (SLL’s) LG12 Emergency Lighting and ICEL documents give guidance on best practice and product certification, with CIBSE Commissioning Code F offering additional guidance.

The Regulatory Reform Order, Approved Documents and BS 5266 cross-reference each other, and should be seen as the main methods of demonstrating compliance. Since 2005, and the introduction of the Fire Regulation Reform Order, the legal imperative for installing emergency lighting systems is the same as for fire-alarm systems. Key changes The main changes in BS 5266 are the introduction of two new levels of emergency lighting – emergency safety lighting and standby lighting.

These have been mentioned in BS EN 1838 Lighting applications – Emergency lighting and BS 5266, but the 2016 version of BS 5266 expands on this. For emergency escape lighting, there is no change in BS 5266, but it is worth noting that the system has to cover all escape routes to the place of safety (BS EN 1838), which may be in the immediate vicinity or away from the building.

This must be adequately lit by the emergency lighting system or an independent power supply, such as public street lighting. Small changes can trigger a larger level of responsibility Emergency safety lighting applies to buildings for which a staged evacuation plan is implemented during power failure. Emergency safety lighting is adequate to allow occupants to stay in an area of the building during a power failure, but is not enough for functional tasks to be continued. The Health and Safety Executive’s document HSG 38 Lighting at Work gives the minimum requirements for this type of lighting. Standby lighting is needed in buildings where functional tasks must continue during power failure. This needs to be 100% of the normal lighting. Who is responsible?

The building owner is required to prepare a risk assessment detailing the emergency-lighting risks they have identified as applying to the occupation of a building. In the case of a multi-occupancy building, the tenants are responsible for doing a risk assessment for their tenanted area, and the landlord is responsible for the common areas. The risk assessments can only be written by the responsible person because they include the management procedures that apply to their occupancy.

This includes: identifying high-risk areas; high-risk or safety-related tasks; and areas where occupants may be required to remain in the case of a power failure. Points of emphasis and high-risk areas are likely to change during the life of a building. (For more, see the expanded version of this article at cibsejournal.com). Who is responsible for emergency lighting? The responsibilities for emergency lighting are generally as follows: Client: to procure and operate safely an emergency lighting system, to ensure competent designers, installers, and maintainers are employed/briefed to procure the system, to risk assess, as necessary appropriate changes to the accepted standards defined by BS5266 and to discharge his responsibilities under Fire Regulation Reform Order 2005.

BS 5266 defines competent person as: ‘person with the relevant current training and experience, and with access to the requisite tools, equipment and information, and capable of carrying out a defined task.’ However it does not define the roles of the parties in the life of an emergency lighting system. The following definitions of roles have been distilled from the standards Designer: to design the emergency lighting systems in accordance with the responsible person’s risk assessment using the Emergency lighting standards and best practice documentation as a baseline to ensure safe escape from the building. Installer: to install the emergency lighting system in accordance with the designer’s documentation to test and commission both photometrically and electrically (as necessary) the system and provide all as fitted documentation in line with the actually installed installation and to handover the system to the client.

Maintainer: to be responsible for the ongoing inspection, testing and maintenance of the system and updating all emergency lighting revisions on to record information and maintaining the log book. Facilities management (FM) teams are aware of the weekly fire-alarm tests and should be aware of the need for a daily visual inspection of the emergency lighting before occupation of the building. BS5266 refers in more detail to competency standards for the designer, installer and the maintainer.

The responsible person must ensure they engage competent people for all stages of procurement and operation of the emergency lighting system, from the time they first occupy the building until they leave. For designers, this would include lighting-design and electrical competency. Central power-supply systems require the design of electrical circuitry, so a qualified electrical engineer needs to be engaged.

Cibse Lighting Guide

An installation using self-contained luminaires could be photometrically calculated and laid out by lighting designers with basic knowledge of electrical engineering, and they would give briefing information to the electrical engineer. The definition of competency is not established within BS 5266 Part 1.

SLL recognises competency as a full member of the society (MSLL) who has sufficient emergency-lighting knowledge through relevant experience. AMSLL and MCIBSE members are not recognised. The British Association of Fire Engineers (BAFE) also has a competency qualification course that can be accessed through the mid-career college. The legal basis of emergency lighting procurement is essentially the same as that for fire regulations, in that the building owner/organisation is the ‘responsible person’ as defined by the regulations. As such, they must ensure the correct provision and operation of the emergency lighting system(s).

Designing with LED luminaires LED luminaires are often considered the first choice source for the majority of emergency lighting. However there are pitfalls to be avoided. It is important to understand the specification and supply chain of any emergency converted general LED luminaire as the introduction of the batteries and invertor into the interior of the luminaire will change the ambient temperature T a within the luminaire. The manufacturer undertaking the conversion would be responsible for re-undertaking the LED thermal testing of the luminaire. Manufacturers who have emergency versions of catalogue products would be expected to have carried out full product testing on the emergency version. If emergency provision is provided from a separate external battery pack it is important for designer and installers to check the full compatibility of the battery unit to deliver the required emergency luminaire lumens and that there is no impact on the published characteristics of the LEDs or drivers. This is important in two-stage design situations where a designer undertakes an initial design and the contractor takes on the final choice of equipment and installation.

Photometrics of LED luminaires vary considerably and vertical illuminances on points of emphasis – for example fire alarm manual call points and first aid points – are quite sensitive to movements within the 2m distance recommended by BS 5266. With LED luminaires the lighting design is much more equipment specific meaning changes of luminaire or manufacturer have to be checked carefully. Typical emergency LED luminaires do not always provide the 5 lux on the face of non-internally illuminated signs, due to their heavily downward based photometry.

Gone are the days of every manufacturers’ 8w bulkhead being the same photometrically. BS 5266 now also specifies that central power-supply systems feeding emergency lighting should be in their own dedicated room. Service life for nickel cadmium batteries is mentioned as being four years. This would indicate that additional proof of the self-contained luminaire’s or battery pack’s ability to produce the required emergency lumens would be needed after four years. This proof might consist of an illumination survey at the 1hr/3hr marks of the annual duration test.

Where occupiers of a building append their own non-illuminated emergency signage, this must also be illuminated by the emergency lighting system under BS 5266. With these amendments, it is easy to see how small changes to a building can trigger a larger level of consideration and responsibility for the responsible person – usually discharged through the FM team. D avid Mooney is an associate at Atkins.