CN202599522U

CN202599522U - Spherical photometer for measuring luminous flux of LED

Info

Publication number: CN202599522U
Application number: CN 201220107962
Authority: CN
Inventors: 刘慧�; 赵伟强; 刘建; 杨臣铸
Original assignee: National Institute of Metrology
Current assignee: National Institute of Metrology
Priority date: 2012-03-21
Filing date: 2012-03-21
Publication date: 2012-12-12
Anticipated expiration: 2022-03-21

Abstract

The utility model provides a spherical photometer for measuring luminous flux of a light-emitting diode (LED). The spherical photometer comprises a photometer, a sphere and a blocking screen. A circular hole with the diameter slightly larger than 50mm is arranged on the sphere and is used for installing a movable spherical wall or a precision diaphragm. A detector of the photometer and the circular hole are located on the equator of the sphere. An auxiliary light source can be installed at a position, symmetrical to the detector, on the equator of the sphere. White neutral defuse reflection materials are sprayed on the inner wall of the sphere, the inner wall of the movable spherical wall and the blocking screen. The upper part and the lower part of the sphere are respectively provided with an opening for installing a fixed support rod of the LED. By installing or not installing the movable spherical wall, the precision diaphragm and the support rod and changing the installation positions of a tested or standard LED and the blocking screen, the measurement of 4pi space, 2pi space and partial luminous flux of the LED specified by a No. CIE127 document is respectively achieved. The spherical photometer for measuring the luminous flux of the LED in the utility model has the advantages of being high in integration, capable of saving space, high in cost performance, convenient to use, high in efficiency and the like.

Description

The spheric photometer of LED luminous flux measurement

Technical field

The utility model belongs to the luminous flux measurement field, relates to the device of the luminous flux of a kind of measurement light emitting diode (hereinafter to be referred as LED).Relate in particular to a kind of relative measurement device that satisfies the measurement LED luminous flux of International Commission on Illumination's publication (CIE 127) defined.

Background technology

Luminous flux is to characterize one of most important parameter of light source luminescent characteristic.The measurement of luminous flux has two kinds of methods: a kind of is absolute method of measurement, and with the luminous intensity of distribution photometer measurement measured light all directions in the space, integral and calculating obtains luminous flux; Another kind is the relative measurement method, uses spheric photometer to compare measurement with the standard sources and the measured light of known luminous flux.Spheric photometer is made up of photometer, spheroid and baffle plate etc.Spheroid is a spherical hollow space; Inwall scribbles diffuse reflector; The light that light source sent is through the ball wall repeatedly after the diffuse reflection; Make the reflection illumination of each point on the whole ball wall identical, the last measured photocurrent relative value (hereinafter to be referred as the photoelectricity flow valuve) of photometric detector of Gu Qiubi is proportional to the luminous flux of light source.When the absorption of measured light and standard sources not simultaneously, use secondary light source to absorb the measurement of modifying factor.

No. 127 files specify of CIE the spheric photometer of three kinds of forms, realize the luminous flux measurement of three kinds of geometric conditions respectively through three spheric photometers, see accompanying drawing 1.Wherein, Fig. 1 (a) is the measurement that is used for the luminous flux in 4 π spaces, is suitable for all luminous LED of front and rear; Fig. 1 (b) is the measurement that is used for the luminous flux in 2 π spaces, is suitable for that the rear portion is not luminous has only anterior luminous LED; Fig. 1 (c) is the measurement of partial luminous flux, is used to measure the luminous flux of LED within a certain solid angle.

In the actual measurement, different to the luminous characteristics of LED and application scenario, the measurement that need select a kind of LED of the carrying out luminous flux in above-mentioned Fig. 1 (a), 1 (b), three kinds of spheric photometers of 1 (c) respectively for use.The measurement that the LED luminous flux will be carried out in calibration test experience chamber need be disposed three integrating spheres and realized that respectively three kinds of geometric formats measure, thereby takies than large space, has increased cost.

Therefore be necessary to provide a kind of spheric photometer, with the LED luminous flux measurement of three kinds of geometric formats of a spheric photometer realization CIE127 files specify, thereby conserve space reduces cost.

The utility model content

The spheric photometer that the utility model provides a kind of LED luminous flux to measure comprises photometer, spheroid and baffle plate, and said photometer comprises photometric detector, and said spheroid is a spherical hollow space; It is characterized in that, open a somewhat larger in diameter on the said spheroid in the circular hole of 50mm, movable balls wall or accurate diaphragm are installed here, photometric detector, circular hole are positioned on the spheroid equator, and the central angle at photometric detector center and circular hole center is at a distance of 45 ° ± 5 °;

The implication of said " somewhat larger in diameter is in the circular hole of 50mm " is meant the diameter of circular hole greater than 50mm and less than 55mm, so that the construction opening diameter is the accurate diaphragm of 50mm, preferred diameter is the circular hole of 52mm.

Circular hole on said movable balls wall and the spheroid closely cooperates and joins with spheroid inside, and the movable balls wall is identical with the radius-of-curvature of spheroid; When the movable balls wall is installed on the circular hole place, be used for the measurement of the luminous flux in 4 π spaces or 2 π spaces;

The inwall of the inwall of said spheroid, movable balls wall and baffle plate evenly spray the neutral diffuse-reflective material of white;

Said accurate diaphragm has the edge of a knife, and opening diameter is 50mm, and ovality is less than 5 μ m, and the side that edge of a knife opening is little is close to the ball wall, closely cooperates with circular hole; When accurate diaphragm is installed on the circular hole place, be used for the measurement of partial luminous flux;

The upper and lower of said spheroid respectively has a perforate, is used to install the fixedly pole of LED, with screw pole one end is locked on the spheroid, and the other end is positioned at ball centre and is used to install LED, and pole is that hollow is so that the electric power conductor of LED passes; When pole is installed, be used for the measurement of the luminous flux in 4 π spaces;

Tested or standard LED is installed on a kind of in center, sidewall or the outside three kinds of positions of ball, said baffle plate be installed on tested or the corresponding three kinds of positions of standard LED in a kind of; Through installing or movable balls wall, accurate diaphragm and pole not being installed, change the installation site of tested or standard LED and baffle plate, realize the measurement of 4 π spaces, 2 π spaces and the partial luminous flux of the LED of No. 127 files specify of CIE respectively.

In the utility model, the diameter of said spheroid is decided according to the power and the physical dimension of light source, can be (0.3-2.0) m, generally selects 0.5m, 1.0m, 1.5m or 2.0m for use.

Said movable balls wall can be selected steel or the aluminum preparation with the spheroid same material, thickness (3-5) mm for use; Easy accessibility, light leakproofness are good; The inwall and the spheroid of movable balls wall spray simultaneously.

It is not yielding that said accurate diaphragm requires to have rigidity, and the preferred hard metal material processing of rigidity high-quality is such as chrome-manganese steel, molybdenum alloy etc.

The inwall of the inwall of said spheroid, movable balls wall and baffle plate evenly spray neutral diffuse-reflective material barium sulphate or teflon.

Said perforate typically have a diameter from (5-15) mm.Said pole can be various materials, and preferably each metalloid material such as aluminium, copper etc., evenly sprays white neutral diffuse-reflective material on it; Pole also can be processed by teflon, and its surface has diffuse reflective nature, and SR and ball inwall are approaching, and smooth in the spectral response of (380-780) nm.

The detector of said photometer (1) can be substituted by spectral radiometer, and its advantage is the measurement that also can be used for the color parameter of light source.The wavelength coverage of used spectral radiometer is (380-780) nm; Sweep spacing is (2-5) nm; The entrance slit of spectral radiometer is near an end of optical fiber, and the other end of optical fiber is installed to photometric detector position.

When the luminous flux in the 4 π spaces that are used to measure LED, tested or standard LED need select for use a kind of of following dual mode to measure according to use: adopt lamp socket at last, light source in mode down, strut fixation is on the top of spheroid at this moment; Adopt lamp socket down, light source is in last mode, this moment, strut fixation was in the bottom of spheroid.

When being used to measure the partial luminous flux of LED, tested or standard LED is installed on the normal direction at the outer accurate diaphragm center of ball, apart from being calculated by d=25/tan (x/2) according to x ° of survey cone angle apart from d of diaphragm.

As a kind of embodiment preferred, on said spheroid equator, secondary light source is installed with the position of said photometric photometric detector symmetry.Under many situations, the size of measured light and standard sources is different with the transparency of glass bulb, when the luminous flux in the 2 π spaces of measuring LED and 4 π spaces, uses secondary light source to absorb the measurement of modifying factor.

Use the method for the spheric photometer measurement LED luminous flux of the utility model, comprise the steps:

(A) measure a kind of of three kinds of forms according to 4 π spaces, 2 π spaces or the partial luminous flux of the LED of No. 127 files specify of CIE; Standard LED, baffle plate are installed in place; Install or movable balls wall, accurate diaphragm and pole are not installed, can be (A1)-any one mode of (A 3)

When (A1) measuring the luminous flux in 4 π spaces; Lamp socket is descending light source in last mode descending perhaps at last light source to select lamp socket; With screw pole one end is locked on the spheroid, is positioned at the other end installation code LED of ball centre, the movable balls wall is installed at the circular hole place on the spheroid; Connect in movable balls wall and the spheroid, corresponding baffle plate is installed;

When (A2) measuring the luminous flux in 2 π spaces, at the sidewall locations installation code LED of ball, the movable balls wall is installed at the circular hole place on the spheroid, connects in movable balls wall and the spheroid, and corresponding baffle plate is installed;

(A3) during the measure portion luminous flux, the external position installation code LED at ball does not install the movable balls wall, and accurate diaphragm is installed at the circular hole place on the spheroid, and corresponding baffle plate is installed;

(B) light standard LED, LED adjusts to rated operational current with standard, treats that its luminous stable back reads photoelectricity flow valuve i from photometer _s

(C) standard LED is replaced by tested LED, tested LED is adjusted to rated operational current, treat that its luminous stable back reads photoelectricity flow valuve i from photometer _t

(D) use formula Φ _t=Φ _s(i _t/ i _s) calculate the luminous flux of tested LED, wherein Φ _tBe the luminous flux of tested LED, Φ _sBe the luminous flux of known standard LED, i _sBe the photoelectricity flow valuve of standard LED, i _tPhotoelectricity flow valuve for tested LED.

When measuring the luminous flux in 2 π or 4 π spaces; Further be included in standard LED and tested LED and absorb the step (E) that absorbs correction under the condition of different: on the installation site of light source, load onto a standard LED and do not light; Light secondary light source, treat the luminous photoelectricity flow valuve A that reads this moment after stable of secondary light source _sTake off standard LED, on same position, load onto tested LED and do not light, read photoelectricity flow valuve A equally _tAbsorption modifying factor α=A of this tested LED then _s/ A _t, revised measured value Φ=Φ _tα, wherein Φ _tThe luminous flux of the tested LED that obtains for said step (D).

When measuring the partial luminous flux of LED, said tested or standard LED is installed on the normal direction at the outer accurate diaphragm center of ball, being calculated by d=25/tan (x/2) according to x ° of survey cone angle apart from d of the accurate diaphragm of distance.

When the luminous flux in the 4 π spaces of measuring LED, said tested or standard LED need select for use a kind of of following dual mode to measure according to uses: adopt lamp socket descending mode at last, light source, strut fixation is on the top of spheroid at this moment; Adopt lamp socket down, light source is in last mode, this moment, strut fixation was in the bottom of spheroid.

The spheric photometer of the utility model; Through installing or not installing movable balls wall, accurate diaphragm and pole; Change the installation site of tested or standard LED and baffle plate; Use same spheric photometer can realize the measurement of the 4 π spaces of the LED of No. 127 files specify of CIE, 2 π spaces and partial luminous flux respectively, have integrated level height, conserve space, cost performance is high, easy to use and the efficient advantages of higher.

Description of drawings

Following with reference to accompanying drawing through reading, to the detailed description that non-limiting example is done, other characteristics, purpose and the advantage of the utility model will become more obvious.

Fig. 1 is three kinds of form spheric photometers that are used for the CIE recommendation of LED measurement, and wherein 1 (a) is the luminous flux of measuring 4 π spaces, and 1 (b) is the luminous flux of measuring 2 π spaces, and 1 (c) is the measure portion luminous flux.

Fig. 2 is the parent map that the utility model preferably can be used for the spheric photometer of three kinds of form LED luminous flux measurements simultaneously, and wherein 2 (a) are the stereographic maps of profile, and 2 (b) are the cut-open views of detector place great circle, and 2 (c) are equatorial plane cut-open views.

Fig. 3 is the synoptic diagram that the preferred spheric photometer of the utility model is used for 4 π spatial light flux measurements, wherein Fig. 3 (a) be lamp socket last light source under measuring method, Fig. 3 (b) is a lamp socket at light source down in last measuring method.

Fig. 4 is the synoptic diagram that the preferred spheric photometer of the utility model is used for 2 π spatial light flux measurements.

Fig. 5 is that the preferred spheric photometer of the utility model is used for the synoptic diagram that partial luminous flux is measured.

Fig. 6 is the synoptic diagram of partial luminous flux definition.

Among the figure: the 1-photometer; 2-movable balls wall; The 3-secondary light source; 4,5, the tested or standard LED of 6-; 7,8, the 9-baffle plate; The 10-perforate; The 11-spheroid; The accurate diaphragm of 12-, the 13-circular hole; The 14-screw; 15-pole

Embodiment

Be described below exemplary with diagram the utility model.This scheme has been included in spheric photometer and the method for application thereof.Certainly, the preferred embodiment of discussing below it will be apparent to those skilled in the art that is exemplary in itself, and can under the situation of scope that does not depart from the utility model and spirit, be changed.But; For clear and accurate; The said exemplary of discussing below can comprise preferred step, method and characteristic, and those of ordinary skills it will be appreciated that these preferred steps, method and characteristic are not the necessary conditions that drops in the utility model scope.

2 to Fig. 6 be described in detail with reference to the accompanying drawings.

Shown in Fig. 2 (a)-2 (c); Spheric photometer comprises photometer 1, the spheroid 11 of diameter 0.5m,

baffle plate

7,8 or 9; The circular hole 13 that to open a diameter on the spheroid 11 be 52mm; Circular hole 13 places are used to install movable balls wall 2 or accurate diaphragm 12, and the detector of photometer 1, secondary light source 3, circular hole 13 are positioned on spheroid 11 equator, and the central angle at the detector center of photometer 1 and circular hole 13 centers is at a distance of 45 °.

In the perforate 10 that a diameter 10mm is respectively opened in the upper and lower of spheroid 11, be used to install and fix the aluminium pole 15 of tested or standard LED 5, pole 15 usefulness screws 14 are locked on the spheroid 11.When measuring the luminous flux in 4 π spaces of LED, need to install pole 15.

Movable balls wall 2 adopt thickness 4mm with the metallic aluminium spheroid same material, movable balls wall 2 closely cooperates with circular hole 13 on the spheroid 11 and joins with spheroid inside, both radius-of-curvature are identical.Accurate diaphragm 12 adopts the chrome-manganese steel material, and opening diameter is 50mm, and ovality is ± 3 μ m, and opening part is processed into edge of a knife type, and the side that edge of a knife opening is little is close to the ball wall, closely cooperates with circular hole 13.When being used to measure the luminous flux in 4 π spaces or 2 π spaces of LED movable balls wall 2 need be installed, precise light door screen 12 is not installed; When being used for the measure portion luminous flux, need accurate diaphragm 12 is installed, movable balls wall 2 is not installed.

The inwall of spheroid 11, the inwall of movable balls wall 2,

baffle plate

7,8,9, and pole 15 sprays barium sulphate simultaneously equably.

On the spheroid equator, secondary light source 3 is installed with the symmetrical position of the detector of photometer 1.

During concrete measuring operation, spheric photometer is laid steadily, the detector of photometer 1 is installed on the spheroid 11, its test surface and joining with spheroid 11; Select one in the

baffle plate

7,8,9 to be installed in the ball, do not install for all the other two, light corresponding with it tested or standard LED, carry out the measurement of luminous flux.Corresponding tested or standard LED 4 of baffle plate 7 wherein, baffle plate 8 corresponding tested or standard LED 5, baffle plate 9 corresponding tested or standard LED 6.

Shown in Fig. 3 (a) or 3 (b), the movable balls wall 2 on the spheroid 11 is installed, and joins with spheroid 11; Baffle plate 8 is installed, and

baffle plate

7,9 is not installed, and pole 15 is fixed on the top or the bottom of spheroid with screw 14; Tested or standard LED 5 lights, and realizes the measurement of the luminous flux in the said 4 π spaces of Fig. 1 (a).

As shown in Figure 4, movable balls wall on the spheroid 11 2 is installed, and connects in the spheroid 11, and baffle plate 7 is installed, and

baffle plate

8,9 is not installed, and tested or standard LED 4 lights, and realizes the measurement of the luminous flux in the said 2 π spaces of Fig. 1 (b).

As shown in Figure 5, the accurate diaphragm 12 on the spheroid 11 is installed, and baffle plate 9 is installed, and

baffle plate

7,8 is not installed, and tested or standard LED 6 lights, and realizes the measurement of the described partial luminous flux of Fig. 1 (c).As shown in Figure 6, the diameter D=50mm of accurate diaphragm, the cone angle x of tested part °=90 ° calculate d=25mm according to d=(D/2)/[tan (x/2)].

The measurement of embodiment 1 LED 4 π spatial light flux

Like Fig. 3 (a), spheric photometer to be laid steadily, the detector of photometer 1 is installed on the spheroid 11, and its test surface and spheroid 11 join; Movable balls wall 2 on the spheroid 11 is installed, and joins with spheroid 11; Baffle plate 8 is installed, and baffle plate 7 is not installed with baffle plate 9; Pole 15 is fixed on the top of spheroid with screw 14; Light standard LED 5, the position of adjustment standard LED 5 makes the detector of photometer 1 be positioned at the center that baffle plate 8 is projected in the shade on spheroid 11 inwalls; Standard LED 5 is adjusted to rated operational current 20mA, after 3 minutes, treat that it luminously stable reads photoelectricity flow valuve i from photometer 1 _s=6362; Extinguish standard LED 5 and be replaced by tested LED 5, and standard LED 5 is identical with tested LED 5 specifications, treat to read photocurrent i from photometer after its luminous stablizing _t=6539; The luminous flux of known standard LED 5 is Φ _s=3.219lm, the luminous flux phi of so tested LED 5 _t=Φ _s(i _t/ i _s)=3.309lm.

The luminous flux measurement in the 2 π spaces of embodiment 2 LED

Like Fig. 4, spheric photometer to be laid steadily, the detector of photometer 1 is installed on the spheroid 11, and its test surface and spheroid 11 join; Movable balls wall 2 on the spheroid 11 is installed, and joins with spheroid 11; Baffle plate 7 is installed, and baffle plate 8 is not installed with baffle plate 9; Installation code LED 4 lights standard LED 4 to the sidewall of ball; Standard LED 4 is adjusted to specified working current, after 3 minutes, treat that it luminously stable reads photoelectricity flow valuve i from photometer _s=3082; Extinguish standard LED 4, be replaced by tested LED 4, and standard LED 4 is identical with tested LED 4 specifications, treat to read photocurrent i from photometer after its luminous stablizing _t=2764; The luminous flux of known standard LED 4 is Φ _s=1.560lm, the luminous flux phi of so tested LED 4 _t=Φ _s(i _t/ i _s)=1.399lm.

The measurement of embodiment 3 led section luminous fluxes

Like Fig. 5, spheric photometer to be laid steadily, the detector of photometer 1 is installed on the spheroid 11, and its test surface and spheroid 11 join; Movable balls wall 2 on the spheroid 11 is not installed, and an accurate diaphragm 12 that diameter is 50mm is installed; Baffle plate 9 is installed, and baffle plate 7 is not installed with baffle plate 8; Installation code LED 6 is to the optical bench of spheroid 11 outsides; And move that to make its position apart from d=25mm apart from accurate diaphragm 12 promptly measure cone angle be x=90 °; The position of adjustment standard LED 6 is located at the normal direction at the center of accurate diaphragm 12, the i.e. normal direction at the center of ball wall opening; Standard LED 6 is adjusted to specified working current 350mA, after 3 minutes, treat that it luminously stable reads photoelectricity flow valuve i from photometer _s=13880; Extinguish standard LED 6, be replaced by tested LED 6, and standard LED 6 is identical with the specification of tested LED6, treat to read photocurrent i from photometer after its luminous stablizing _t=14146; The luminous flux of known standard LED6 is Φ _s=78.30lm, the luminous flux phi of so tested LED 6 _t=Φ _s(i _t/ i _s)=79.80lm.

Embodiment 4 absorbs the measurement of the LED 4 π spatial light flux of correction

Like Fig. 3 (a), spheric photometer to be laid steadily, the detector of photometer 1 is installed on the spheroid 11, and its test surface and spheroid 11 join; Movable balls wall 2 on the spheroid 11 is installed, and joins with spheroid 11; Baffle plate 8 is installed, and baffle plate 7 is not installed with baffle plate 9; Pole 15 is fixed on the top of spheroid with screw 14; Light standard LED 5, the position of adjustment standard LED 5 makes the detector of photometer 1 be positioned at the center that baffle plate 8 is projected in the shade on spheroid 11 inwalls; Standard LED 5 (hyaline test) is adjusted to rated operational current 20mA, after 3 minutes, treat that it luminously stable reads photoelectricity flow valuve i from photometer 1 _s=6362; Extinguish standard LED 5 and be replaced by tested LED 5 (milky white shell), treat to read photocurrent i from photometer after its luminous stablizing _t=6423; Extinguish tested LED 5, light the secondary light source 3 in the ball, treat to read photoelectricity flow valuve A at this moment behind secondary light source 3 luminous the stablizing _t=4642.Take off tested LED 5, on identical position, load onto standard LED 5 (not lighting), read photoelectricity flow valuve A _S=4655; Then this tested LED 5 absorbs modifying factor α=A _s/ A _t=1.00280.The luminous flux of known standard LED 5 is Φ _s=3.219lm, luminous flux phi=Φ of tested LED 5 among the embodiment 1 so _s(i _t/ i _s) α=3.259lm.

Can know by the foregoing description; The spheric photometer of the utility model can be realized the measurement to 4 π spaces, 2 π spaces and the partial luminous flux of the LED of No. 127 files specify of CIE efficiently, easily and accurately in a ball, integrated level height, conserve space, cost performance height.

Claims

1. the spheric photometer of a LED luminous flux measurement comprises photometer (1), spheroid (11) and baffle plate (7,8 or 9), and said photometer (1) comprises photometric detector, and said spheroid (11) is a spherical hollow space; It is characterized in that; Open the circular hole (13) of a somewhat larger in diameter on the said spheroid (11) in 50mm; Be used to install movable balls wall (2) or accurate diaphragm (12) here; The detector of photometer (1), circular hole (13) are positioned on spheroid (11) equator, and the central angle at the detector center of photometer (1) and circular hole (13) center is at a distance of 45 ° ± 5 °;

Said movable balls wall (2) closely cooperates with circular hole (13) and joins with spheroid inside, and movable balls wall (2) is identical with the radius-of-curvature of spheroid (11); When movable balls wall (2) is installed on circular hole (13) when locating, be used for the measurement of the luminous flux in 4 π spaces or 2 π spaces;

The inwall of the inwall of said spheroid (11), movable balls wall (2) and baffle plate (7,8 or 9) evenly spray white neutral diffuse-reflective material;

Said accurate diaphragm (12) has the edge of a knife, and opening diameter is 50mm, and ovality is less than 5 μ m, and the side that edge of a knife opening is little is close to the ball wall, closely cooperates with circular hole (13); When accurate diaphragm (12) is installed on circular hole (13) when locating, be used for the measurement of partial luminous flux;

The upper and lower of said spheroid (11) respectively has a perforate (10); Be used to install the fixedly pole (15) of LED; With screw (14) pole (15) one ends are locked on the spheroid (11); The other end is positioned at spheroid (11) center, is used to install LED, and pole (15) is that hollow is so that the electric power conductor of LED (5) passes; When pole (15) is installed, be used for the measurement of the luminous flux in 4 π spaces;

Tested or standard LED (4,5 or 6) is installed on a kind of in center, sidewall or the outside three kinds of positions of ball, said baffle plate (7,8 or 9) be installed on the corresponding three kinds of positions of tested or standard LED (4,5 or 6) in a kind of; Through installing or not installing movable balls wall (2), accurate diaphragm (12) and pole (15); Change tested or standard LED (4; 5 or 6) and baffle plate (7; 8 or 9) installation site is realized the measurement of 4 π spaces, 2 π spaces and the partial luminous flux of the LED of No. 127 files specify of CIE respectively.

2. according to the said spheric photometer of claim 1, it is characterized in that the diameter of said spheroid (11) is decided according to the power and the physical dimension of light source.

3. according to the said spheric photometer of claim 1, it is characterized in that said movable balls wall (2) adopts steel identical with spheroid (11) material or aluminium preparation.

4. according to the said spheric photometer of claim 1, it is characterized in that said accurate diaphragm (12) adopts the hard metal material processing of rigidity high-quality to form.

5. according to the said spheric photometer of claim 1, it is characterized in that said pole (15) perhaps sprays the Metallic rod of white neutral diffuse-reflective material for teflon rod.

6. according to claim 1 or 5 said spheric photometers, it is characterized in that said diffuse-reflective material is barium sulphate or teflon.

7. according to the said spheric photometer of claim 1; It is characterized in that; Said tested or standard LED (5) need select for use a kind of of following dual mode to install according to use: adopt lamp socket at last, light source in mode down, pole (15) is fixed on the top of spheroid (11) at this moment; Adopt lamp socket down, light source is in last mode, pole this moment (15) is fixed on the bottom of spheroid (11).

8. according to the said spheric photometer of claim 1; It is characterized in that; Said tested or standard LED (6) is installed on the normal direction at outer accurate diaphragm (12) center of ball, being calculated by d=25/tan (x/2) according to x ° of survey cone angle apart from d of the accurate diaphragm of distance (12).

9. according to the said spheric photometer of claim 1, it is characterized in that the detector of said photometer (1) can be substituted by spectral radiometer.

10. according to the said spheric photometer of claim 1, it is characterized in that, further, on said spheroid (11) equator, secondary light source (3) is installed with the symmetrical position of the detector of said photometer (1).

11., it is characterized in that the diameter of said spheroid (11) is (0.3-2.0) m according to the said spheric photometer of claim 2.

12., it is characterized in that the diameter of said spheroid (11) is 0.5m according to the said spheric photometer of claim 11.