CN204948415U - Room light leading lights Optimizing Control System - Google Patents

Abstract

The utility model discloses a kind of room light leading lights Optimizing Control System, comprising: photoconduction shadow shield, lighting, terminal control unit, telegon, hybrid wireless sensor, illumination monitoring center and monitor terminal; Telegon is connected with terminal control unit and hybrid wireless sensor respectively, and terminal control unit is connected with photoconduction shadow shield and lighting respectively, and illumination monitoring center is connected with telegon and monitor terminal respectively; Hybrid wireless sensor, photoconduction shadow shield and lighting are all disposed in the interior.This system can overcome photoconductive tube lighting system when conducting natural daylight into indoor, the defect of the brightness of light can not be adjusted according to indoor occupant activity, personnel amount and interior space size, structure is simple, uses, easy for installation, simple to operate, brightness of illumination is easy to adjust, cost is low, intelligent, applied widely, long service life, safe and reliable.

Description

Room light leading lights Optimizing Control System

Technical field

The utility model relates to solar photovoltaic technology field, particularly a kind of room light leading lights Optimizing Control System.

Background technology

Solar energy also result in the extensive concern of countries in the world as a kind of clean energy resource, and manufacturing enterprise both domestic and external quite enlivens the research and development of products utilized about solar energy " heat ", but the product utilized for solar energy " light " is relatively less.The more energy resource consumption using natural daylight can reduce whole building in architectural lighting, light pipe lighting system can make natural daylight more fully be applied in architectural lighting, thus saves a large amount of electric power resources.

Light pipe lighting system can be transmitted to the inaccessiable place of other method natural daylight.Light pipe lighting system neither affects existing building structure, and energy free consumption again, has waterproof, dust-proof, and the effect of sound insulation can improve Indoor Environmental Quality, allows people live in natural daylight and natural fresh air, work, amusement.This is a kind of energy-conservation, the Land use systems of the sunlight of environmental protection and health.

But when natural daylight conducts into indoor by photoconductive tube lighting system, can not adjust the brightness of light according to indoor occupant activity, personnel amount and interior space size, this can bring certain loss to user.

Given this, how to overcome photoconductive tube lighting system when conducting natural daylight into indoor, personnel amount movable according to indoor occupant and the interior space size defect that adjusts the brightness of light can not become the current technical issues that need to address.

Utility model content

For defect of the prior art, the utility model provides a kind of room light leading lights Optimizing Control System, can overcome photoconductive tube lighting system when conducting natural daylight into indoor, the defect of the brightness of light can not be adjusted according to indoor occupant activity, personnel amount and interior space size, structure is simple, uses, easy for installation, simple to operate, brightness of illumination is easy to adjust, cost is low, intelligent, applied widely, long service life, safe and reliable.

The utility model provides a kind of room light leading lights Optimizing Control System, comprising: photoconduction shadow shield, lighting, terminal control unit, telegon, hybrid wireless sensor, illumination monitoring center and monitor terminal;

Described telegon is connected with described terminal control unit and described hybrid wireless sensor respectively, described terminal control unit is connected with described photoconduction shadow shield and described lighting respectively, and described illumination monitoring center is connected with described telegon and described monitor terminal respectively;

Described hybrid wireless sensor, described photoconduction shadow shield and described lighting are all disposed in the interior;

Wherein, described hybrid wireless sensor gathers indoor illuminance and indoor occupant movable information, and the illuminance of described indoor and indoor occupant movable information are sent to described illumination monitoring center by described telegon;

Described telegon is passed through to described terminal control unit sending controling instruction according to the illuminance of described indoor and indoor occupant movable information in described illumination monitoring center, and then controls the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor;

Or, the illuminance of described indoor and indoor occupant movable information are sent to monitor terminal by described illumination monitoring center, and receive the command information of described monitor terminal transmission, according to described command information, by described telegon to described terminal control unit sending controling instruction, and then control the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor.

Optionally, described illumination monitoring center is connected with database, for storing illuminance and the indoor occupant movable information of the indoor of reception.

Optionally, described telegon has GPRS interface, and described illumination monitoring center is connected with described telegon by the 3G network base station in the Internet.

Optionally, described telegon has Wifi interface, and described illumination monitoring center is connected with described telegon by the Wifi router in the Internet.

Optionally, described terminal control unit and described hybrid wireless sensor all adopt Zigbee wireless telecommunications to be connected with described telegon.

Optionally, described illumination monitoring center is connected with described monitor terminal by the Internet.

Optionally, described monitor terminal is remote terminal, and/or mobile terminal.

Optionally, described lighting, comprising: key lighting light fixture and assisted illuminating lamp.

Optionally, key lighting light fixture is light pipe lighting.

Optionally, described assisted illuminating lamp is LED illumination lamp.

The room light leading lights Optimizing Control System that the utility model provides, can overcome photoconductive tube lighting system when conducting natural daylight into indoor, personnel amount movable according to indoor occupant and interior space size can not adjust the defect of the brightness of light, structure is simple, use, easy for installation, simple to operate, brightness of illumination is easy to adjust, and cost is low, intelligent, applied widely, long service life, safe and reliable.

Accompanying drawing explanation

The structural representation of a kind of room light leading lights Optimizing Control System that Fig. 1 provides for the utility model one embodiment.

Embodiment

Below in conjunction with drawings and Examples, embodiment of the present utility model is described in further detail.Following examples for illustration of the utility model, but are not used for limiting scope of the present utility model.

Fig. 1 shows the structural representation of the room light leading lights Optimizing Control System that the utility model one embodiment provides, as shown in Figure 1, the room light leading lights Optimizing Control System that the utility model provides, comprising: photoconduction shadow shield, lighting, terminal control unit, telegon, hybrid wireless sensor, illumination monitoring center and monitor terminal;

Described telegon is connected with described terminal control unit and described hybrid wireless sensor respectively, described terminal control unit is connected with described photoconduction shadow shield and described lighting respectively, and described illumination monitoring center is connected with described telegon and described monitor terminal respectively;

Described hybrid wireless sensor, described photoconduction shadow shield and described lighting are all disposed in the interior;

Wherein, described hybrid wireless sensor gathers indoor illuminance and indoor occupant movable information, and the illuminance of described indoor and indoor occupant movable information are sent to described illumination monitoring center by described telegon;

Described telegon is passed through to described terminal control unit sending controling instruction according to the illuminance of described indoor and indoor occupant movable information in described illumination monitoring center, and then controls the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor;

Or, the illuminance of described indoor and indoor occupant movable information are sent to monitor terminal by described illumination monitoring center, and receive the command information of described monitor terminal transmission, according to described command information, by described telegon to described terminal control unit sending controling instruction, and then control the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor.

In a particular application, described in the present embodiment, illumination monitoring center is connected with database, for storing illuminance and the indoor occupant movable information of the indoor of reception.

In a particular application, telegon described in the present embodiment has general packet radio service technology (GeneralPacketRadioService, be called for short GPRS) interface, described illumination monitoring center is by the G mobile communication (3rd-Generation in the Internet, being called for short 3G) (namely network base station be connected with described telegon, communication between described telegon and described illumination monitoring center adopts GPRS wireless communication technique, and communications protocol is TCP/IP communications protocol).

In a particular application, telegon described in the present embodiment has Wireless Fidelity (WIreless-FIdelity is called for short Wifi) interface, and described illumination monitoring center is connected with described telegon by the Wifi router in the Internet.

In a particular application, terminal control unit described in the present embodiment and described hybrid wireless sensor all adopt ZigBee protocol Zigbee wireless telecommunications to be connected (namely with described telegon, communication between described telegon and described terminal control unit, described hybrid wireless sensor all adopts ZigBee wireless communication technique, and communications protocol is that IEEE802.15.4 & ZigBee is compatible).

In a particular application, described in the present embodiment, illumination monitoring center is connected with described monitor terminal by the Internet.

In a particular application, monitor terminal described in the present embodiment is remote terminal, and/or mobile terminal.

The room light leading lights Optimizing Control System of the present embodiment, can overcome photoconductive tube lighting system when conducting natural daylight into indoor, personnel amount movable according to indoor occupant and interior space size can not adjust the defect of the brightness of light, structure is simple, use, easy for installation, simple to operate, brightness of illumination is easy to adjust, and cost is low, intelligent, applied widely, long service life, safe and reliable.

In a particular application, described in the present embodiment, telegon parameter is as shown in table 1 below:

Table 1

In a particular application, described in the present embodiment, terminal control unit parameter is as shown in table 2 below:

Table 2

Parameter name	Technical parameter
		Model	TYCON22.2.Z.31
Power supply	220VAC±15％

Power consumption	≤6W
		Upstream Interface type	Zigbee wireless communication interface
Upstream Interface agreement	IEEE802.15.4&ZigBee is compatible
		Up-link wireless transmit frequency band	2.4GHz
Up-link wireless transmitting power	-6dbm
		Up-link wireless receiving sensitivity	-97dbm
Up-link wireless transmission rate	300kbps
		Up outdoor communication distance	300 meters
Up indoor communication distance	30 meters
		Control port	1 tunnel
Relay port rated operational current	2A
		Brightness adjustment control port	1-10V
Shell protection grade	IP65
		Overall dimension	L129*W67*H28mm
Color of shell	Black
		Length of cable	30cm

In a particular application, described in the present embodiment, hybrid wireless sensor terminal parameter is as shown in table 3 below:

Table 3

Parameter name	Technical parameter
		Model	TYSEN05.A.11
Power supply	220VAC±15％
		Power consumption	≤6W
Upstream Interface type	Zigbee wireless communication interface
		Upstream Interface agreement	IEEE802.15.4&ZigBee is compatible
Up-link wireless transmit frequency band	2.4GHz
		Up-link wireless transmitting power	-6dbm
Up-link wireless receiving sensitivity	-97dbm
		Up-link wireless transmission rate	300kbps
Up outdoor communication distance	100 meters
		Up indoor communication distance	20 meters
Illumination photometry scope	0-5000lux
		Illumination photometry error	±60lux+3％
Human motion induction range	Maximum 10.5 meters (diameters)
		Shell protection grade	IP30
Overall dimension	D100*H41mm
		Color of shell	White
Mounting means	Ceiling is installed
		Length of cable	30cm

For example, the parameter of native system is as follows:

1) system context :-40 DEG C ~ 55 DEG C;

2) system works power supply: the power range of AC187V ~ 253V, 50Hz ± 1Hz;

3) system command time of delay :≤5min.

In a particular application, lighting described in the present embodiment, can comprise: key lighting light fixture and assisted illuminating lamp.

In a particular application, the present embodiment key lighting light fixture is light pipe lighting.

In a particular application, assisted illuminating lamp described in the present embodiment is light-emitting diode (LightEmittingDiode is called for short LED) lighting.

In an embody rule, for example, 1 station terminal controller exports 2 tunnel control signals, can control 2 LED illumination lamp respectively at most.

Further, described illumination monitoring center can control the brightness of any 1 group of lighting by the output port controlling described terminal control unit.

Will be understood that, in an embody rule, light pipe lighting is as key lighting, and LED illumination lamp is as floor light, and the indoor illumination intensity upper limit is 200lx (configurable), and illumination lower limit is 37lx (configurable); Actual illumination, lower than preset first threshold value (i.e. illumination lower limit), does not regulate illumination when there is no personnel activity; Actual illumination is lower than preset first threshold value (i.e. illumination lower limit), and when having personnel activity, preferentially regulate the luminous flux of key lighting, if the luminous flux of key lighting be adjusted to maximum after, indoor actual illumination is still lower than preset first threshold value, then progressively increase the brightness of floor light, until the illumination of indoor is higher than preset first threshold value; Actual illumination is higher than the brightness preferentially reducing floor light time default Second Threshold (i.e. the illumination upper limit), if after floor light cuts out, indoor actual illumination still higher than default Second Threshold, then progressively reduces the luminous flux of key lighting, until the illumination of indoor is lower than default Second Threshold.

Will be understood that, native system can control by on-site manual, and by mobile terminal and remote terminal for example, described remote terminal can be personal computer (personalcomputer, abbreviation PC); Native system can the brightness of manual adjustments light pipe lighting, LED illumination lamp at the scene, for scene illumination Non-follow control and lighting apparatus inspection and maintenance; Native system can remote manual and timing controlled, by the brightness of electronic map interface manual adjustments light pipe, LED flat lamp, by the plan of establishment timing controlled, and the brightness of timing controlled light pipe, LED flat lamp.

Will be understood that, the Interface classification in monitor terminal described in the present embodiment is as follows:

(1) login interface;

(2) subscriber administration interface;

(3) software design patterns interface;

(4) electronic map interface;

(5) automatic control and management interface;

(6) time control interface;

(7) Report Server Management interface;

(8) alarming and managing interface;

(9) data management interface;

Interface function demand in monitor terminal described in the present embodiment is as follows:

1) log-in interface: log in control system after can realizing filling in username and password.

2) subscriber administration interface: can realize user's increase, amendment, delete function, user should be able to be divided into keeper and operator's authority; Administrator right can carry out all operations of control system; Operator's authority can be carried out lamp control operation, checked form and check journalizing, can not revise software design patterns.

3) software design patterns interface: the setting of software communication policing port can be realized, telegon communication setting, equipment outage time are arranged.

4) electronic map interface: provide indoor electronic chart, can the brightness of each group light fixture of Non-follow control, can increase, deletes and revise terminal control unit information newly, can display terminal controller operating state, can show the operating state that each organizes controlled light fixture.

5) automatic control and management interface: lamp fabric anomaly, lamp group and transducer binding management, illumination control interval management function are provided; Lamp fabric anomaly: any controlled light fixture and controlled light pipe can be combined as a lighting lamp group.Lamp group and transducer binding management: any lamp group and any sensor are bound, realize lamp group and to automatically adjust brightness according to the data of binding transducer, illumination control interval manages: can arrange illumination upper control limit and lower limit.

6) time control interface: the management of lamp fabric anomaly, timing mode, lamp group and timing binding management function are provided; Lamp fabric anomaly: any controlled light fixture and controlled light pipe can be combined as a lighting lamp group; Timing mode manages: arranged fill order according to 24 hours, arranging the execution cycle is: every day, weekly, monthly, separately once, can specifically select weekly perform Monday to Sunday which day or which weekly day, monthly specifically can select which execution monthly, once can select perform exact date separately; Lamp group is bound with timing and is arranged management: any lamp group and arbitrary timing pattern are bound, realize lamp group according to timing mode requirement work.

7) Report Server Management interface, following form should be able to be provided, energy consumption form: (this form energy consumption statistic value is only reference value to provide fixed time section intraoral illumination system energy consumption situation history report, and there is error between actual consumption, energy accounting can not be carried out as illuminator actual consumption).Log form: the log form that fixed time section intraoral illumination system is provided.Warning message form: the warning message form formulated and formulate type of alarm in the time period is provided

8) alarming and managing interface: system provides following warning: telegon is reached the standard grade, the prompting that goes offline, control appliance fault alarm, lighting fault alarm, alarming and managing interface should be able to provide warning message to show and warning message query function.

9) data management interface: software data maintenance function is provided.

The room light leading lights Optimizing Control System of the present embodiment, can overcome photoconductive tube lighting system when conducting natural daylight into indoor, personnel amount movable according to indoor occupant and interior space size can not adjust the defect of the brightness of light, structure is simple, use, easy for installation, simple to operate, brightness of illumination is easy to adjust, and cost is low, intelligent, applied widely, long service life, safe and reliable.

Last it is noted that above each embodiment is only in order to illustrate the technical solution of the utility model, be not intended to limit; Although be described in detail the utility model with reference to foregoing embodiments, those of ordinary skill in the art is to be understood that: it still can be modified to the technical scheme described in foregoing embodiments, or carries out equivalent replacement to wherein some or all of technical characteristic; And these amendments or replacement, do not make the essence of appropriate technical solution depart from the scope of claim of the present utility model protection.

Claims (10)

1. a room light leading lights Optimizing Control System, is characterized in that, comprising: photoconduction shadow shield, lighting, terminal control unit, telegon, hybrid wireless sensor, illumination monitoring center and monitor terminal;

Described telegon is connected with described terminal control unit and described hybrid wireless sensor respectively, described terminal control unit is connected with described photoconduction shadow shield and described lighting respectively, and described illumination monitoring center is connected with described telegon and described monitor terminal respectively;

Described hybrid wireless sensor, described photoconduction shadow shield and described lighting are all disposed in the interior;

Wherein, described hybrid wireless sensor gathers indoor illuminance and indoor occupant movable information, and the illuminance of described indoor and indoor occupant movable information are sent to described illumination monitoring center by described telegon;

Described telegon is passed through to described terminal control unit sending controling instruction according to the illuminance of described indoor and indoor occupant movable information in described illumination monitoring center, and then controls the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor;

Or, the illuminance of described indoor and indoor occupant movable information are sent to monitor terminal by described illumination monitoring center, and receive the command information of described monitor terminal transmission, according to described command information, by described telegon to described terminal control unit sending controling instruction, and then control the illuminance that described terminal control unit controls described photoconduction shadow shield and described lighting adjustment indoor.

2. room light leading lights Optimizing Control System according to claim 1, is characterized in that, described illumination monitoring center is connected with database, for storing illuminance and the indoor occupant movable information of the indoor of reception.

3. room light leading lights Optimizing Control System according to claim 1, it is characterized in that, described telegon has GPRS interface, and described illumination monitoring center is connected with described telegon by the 3G network base station in the Internet.

4. room light leading lights Optimizing Control System according to claim 1, it is characterized in that, described telegon has Wifi interface, and described illumination monitoring center is connected with described telegon by the Wifi router in the Internet.

5. room light leading lights Optimizing Control System according to claim 1, is characterized in that, described terminal control unit and described hybrid wireless sensor all adopt Zigbee wireless telecommunications to be connected with described telegon.

6. room light leading lights Optimizing Control System according to claim 1, is characterized in that, described illumination monitoring center is connected with described monitor terminal by the Internet.

7. room light leading lights Optimizing Control System according to claim 6, is characterized in that, described monitor terminal is remote terminal, and/or mobile terminal.

8. room light leading lights Optimizing Control System according to claim 1, it is characterized in that, described lighting, comprising: key lighting light fixture and assisted illuminating lamp.

9. room light leading lights Optimizing Control System according to claim 8, is characterized in that, key lighting light fixture is light pipe lighting.

10. room light leading lights Optimizing Control System according to claim 8, is characterized in that, described assisted illuminating lamp is LED illumination lamp.