Patent Publication Number: US-10781979-B2

Title: LED bulb lamp

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS AND PRIORITY CLAIM 
     This application claims the benefit under 35 U.S.C. § 371 to International Application Number PCT/CN2015/090815 filed on Sep. 25, 2015 which claims the priority of Chinese Patent Application No. ‘201410510593.6’, filed on Sep. 28, 2014, 
     Chinese Patent Application No. ‘201510053077.X’, filed on Feb. 02, 2015, 
     Chinese Patent Application No. ‘201510489363.0’, filed on Aug. 07, 2015, and 
     Chinese Patent Application No. ‘201510555889.4’, filed on Sep. 02, 2015 The entire disclosures of said applications are incorporated by reference herein for all purposes. 
     FIELD OF THE INVENTION 
     The disclosure relates to the lighting field, in particular, an LED bulb lamp. 
     BACKGROUND 
     LED lamps have the advantages of long service life, small size and environmental protection, etc., so their applications are increasing more and more. However, the light emitting surface of the LED lamps generally is small due to the LED packaging holder and the substrate which blocks the light, and the LED lamps presents the status of lighting in half of circumference where the angle of the light distribution is less than 180 degree. 
     To achieve a similar light distribution with incandescent lamp of which the light distribution is more than 180 degree, some LED bulb lamps adopt COB (Chip On Board) integrated light sources and is configured with light distribution lens, and some adopt SMD (Surface Mount Technology) light sources arranged on the substrate in an encircling manner . Nevertheless, the light shape curves of these LED bulb lamps are not smooth and have higher local jitter, which result in a situation in which the brightness transits unevenly. 
     In addition, the traditional LED bulb lamp generally has a glass lamp housing which is fragile and the glass fragments can hurt users easily, further, after being broken, the exposed and charged part in the lamp body, such as the light source, solder joints on the substrate or the wires on the lamp substrate etc., will lead to an accident of electric shock easily and result in the risk of personal safety. 
     SUMMARY OF THE INVENTION 
     The disclosure relates to an LED bulb lamp, comprising: an LED lamp substrate having at least one LED light source mounted thereon; and an electrical isolation assembly disposed on the LED lamp substrate, wherein, the electrical isolation assembly electrically isolates the LED lamp substrate&#39;s charged part from outside of the LED lamp substrate. 
     Preferably, the electrical isolation assembly comprising: an electrical isolation unit covering the LED lamp substrate for electrically isolating the charged part on the LED lamp substrate from outside of the LED lamp substrate; and a light processing unit disposed on the electrical isolation unit for converting the outputting direction of the light emitted by the LED light sources. 
     Preferably, the electrical isolation unit and the light processing unit are integrally formed. 
     Preferably, the electrical isolation unit is made of electrically insulating materials with high reflectivity. 
     Preferably, the light processing unit is a cup-shaped structure comprising a main body, a bottom portion and a top portion, wherein the main body is between the bottom portion and top portion. 
     Preferably, the bottom portion is formed with a plurality of through holes, while electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources. The main body comprises a reflecting surface formed on an inside surface of the main body, and the LED light sources on the LED lamp substrate are arranged inside the main body in an encircling manner, so that the light emitted by each of the LED light sources is reflected towards inside of the main body by the reflecting surface. 
     Preferably, the electrical isolation assembly further comprises an extending portion which is outwardly extended from the circumferential of the bottom portion and arranged to the light processing unit, and the extending portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources on the LED lamp substrate. The main body comprises a reflecting surface formed on an outside surface of the main body, and the LED light sources on the LED lamp substrate are arranged outside the main body in an encircling manner, so that the light emitted by each of the LED light sources is reflected towards outside of the main body by the reflecting surface. 
     Preferably, the bottom portion is hollowed out and the main body is a camber surface. The main body comprises a reflecting surface formed on an outside surface of the main body, and wherein, the LED light sources on the LED lamp substrate are arranged under the light processing unit in an encircling manner so that one part of each of the LED light sources are exposed outside the main body, one part are located under the main body and the rest are exposed inside the main body, such that the light emitted by the part of each of the LED light sources exposed outside the main body is reflected towards outside of the main body by the reflecting surface, the light emitted by the part of each of the LED light sources located under the main body go towards the outside right along the main body from the bottom up, and the light emitted by the rest of each of the LED light sources exposed inside the main body are outputted directly towards the lamp housing of the LED bulb lamp. 
     Preferably, the main body is a camber surface and the main body comprises a reflecting surface formed on an outside surface of the main body, and wherein, the LED light sources on the LED lamp substrate are arranged under the light processing unit in an encircling manner so that one part of the LED light sources are exposed outside the main body, one part are located under the main body, such that the light emitted by the part of each of the LED light sources exposed outside the main body are reflected towards outside of the main body by the reflecting surface, and the light emitted by the part of each of the LED light sources located under the main body go towards outside right along the main body from the bottom up. 
     Preferably, the bottom portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources. The main body is a camber surface and the main body comprises a reflecting surface formed on an outside surface of the main body, and wherein the LED lamp substrate include two sets of LED light sources distributed in an encircling manner, wherein, the first set of LED light sources are arranged inside the main body in an encircling manner and the light emitted by each of the light sources of this set are outputted directly to the lamp housing of the LED bulb lamp, and wherein, the second set of LED light sources are arranged under the light processing unit in an encircling manner so that one part of the LED light sources in this set are exposed outside the main body, one part are located under the main body, such that the light emitted by the part of each of the LED light sources exposed outside the main body are reflected towards outside of the main body by the reflecting surface, and the light emitted by the part of each of the LED light sources located under the main body go towards outside right along the main body from the bottom up, wherein, the first set of the LED light sources are corresponding to the through holes formed on the bottom portion. 
     Preferably, the bottom portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources. The main body is a camber surface, and the main body comprises a reflecting surface formed on an outside surface and an inside surface of the main body, and wherein, the LED lamp substrate includes two sets of LED light sources distributed in an encircling manner , wherein, the first set of LED light sources are exposed inside the main body in an encircling manner and the light emitted by each of the light sources of this set is reflected towards inside of the LED bulb lamp by the reflecting surface of the inside surface, and wherein, the second set LED light sources are arranged under the light processing unit in an encircling manner so that one part of each of the LED light sources in this set are exposed outside the main body and one part are located under the main body, such that the light emitted by the part of each of the LED light sources is reflected towards outside direction of the main body by the reflecting surface of the outside surface, and the light emitted by the part of each of the LED light sources located under the main body go toward outside right along the main body from the bottom up, wherein, the first set of LED light sources are corresponding to the through holes formed on the bottom portion. 
     Preferably, the bottom portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources. In addition, the electrical isolation assembly further comprises a extending portion which is outwardly extended from the circumferential of the bottom portion and arranged to the light processing unit, wherein, the extending portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the extending portion and the LED light sources on the LED lamp substrate. The main body comprises a reflecting surface formed on an outside surface of the main body, and wherein, the LED lamp substrate includes two sets of LED light sources distributed in an encircling manner , wherein, the first set of LED light sources are arranged inside the main body in an encircling manner and the light emitted by each of the light sources of this set are outputted to the lamp housing of the LED bulb lamp directly, and wherein, the second set of LED light sources are arranged outside the cut body in an encircling manner, so that the light emitted by each of the LED light sources in this set is reflected towards outside of the main body by the reflecting surface, wherein, the first set of LED light sources are corresponding to the through holes formed on the bottom portion, and the second set of LED light sources are corresponding to the through holes formed on the extending portion. 
     Preferably, the bottom portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the bottom portion and the LED light sources. In addition, the electrical isolation assembly further comprises an extending portion which is outwardly extended from the circumferential of the bottom portion and arranged to the light processing unit, and the extending portion is formed with a plurality of through holes, while the electrical isolation unit is formed with a plurality of through holes corresponding to the through holes on the extending portion and the LED light sources on the LED lamp substrate. The main body comprises a reflecting surface formed on an outside surface and an inside surface of the main body, and wherein, the LED lamp substrate includes two sets of LED light sources distributed in an encircling manner, wherein, the first set of LED light sources are arranged inside the main body in an encircling manner and the light emitted by each of the light sources of this set is reflected towards inside of the LED bulb lamp by the reflecting surface of the inside surface, and wherein, the second set of LED light sources are arranged outside the main body in an encircling manner, so that the light emitted by each of the LED light sources in this set is reflected towards outside of the main body by the reflecting surface of the outside surface, wherein, the first set of LED light sources are corresponding to the through holes formed on the bottom portion, the second set of LED light sources are corresponding to the through holes formed on the extending portion. 
     Preferably, in the various embodiments discussed above, the size of the through hole on the bottom portion and the extending portion is equal to or slightly bigger than the size of the LED light source. 
     Preferably, the LED bulb lamp further comprises a lamp housing, wherein, the inside surface or outside surface of the lamp housing or both are coated with an adhesive film, and the thickness of the adhesive film is related to total weight of the LET bulb lamp. In one embodiment, the thickness of the adhesive film is 200 μm˜300 μm if the total weight of the LET bulb lamp is larger than 100 g. In another embodiment, the thickness of the adhesive film is 40 μm˜90 μm if the total weight of the LET bulb lamp is smaller than 80 g. 
     Preferably, the LED bulb lamp further comprises a lamp housing, wherein, the inside surface or outside surface of the lamp housing or both are coated with a diffusion film. In one embodiment, the main ingredient of the diffusion film is selected from at least one of calcium carbonate, calcium halophosphate and aluminum oxide. 
     Preferably, the LED bulb lamp further comprises a lamp housing, wherein, the inside surface of the lamp housing is coated with a reflecting film, the reflecting film being coated in an area which has a certain angle with the central axis of the LED bulb lamp. In an embodiment, the main ingredient of the reflecting film is barium sulfate. In an embodiment, the angle is in the range of 0 degree˜60 degree. In a embodiment, the angle is in the range of 0 degree˜45 degree. In an embodiment, the thickness of the reflecting film can gradually reduced from the central axis of the LED bulb lamp. 
     According to the LED bulb lamp of the disclosure, it can protect user from contacting the charged part inside the lamp housing when the LED bulb lamp is broken and thereby avoid electric shock accidents. In addition, the directions of the light emitted by the LED light sources can be changed to achieve different kinds of lighting effects according to the LED bulb lamp of the disclosure. 
    
    
     
       DESCRIPTION OF THE DRAWINGS 
         FIG. 1  illustrates a longitudinal sectional view of the LED bulb lamp along the central axis according to an embodiment; 
         FIG. 2  illustrates an exploded view of the LED bulb lamp according to an embodiment; 
         FIG. 3  illustrates a structural schematic view of the electrical isolation assembly, the LED lamp substrate and the radiator after being assembled together according to an embodiment; 
         FIG. 4  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to an embodiment; 
         FIG. 5  illustrates an exemplary light distribution curve view of the LED bulb lamp according to an embodiment; 
         FIG. 6  illustrates a structural schematic view of the electrical isolation assembly, the LED lamp substrate and the radiator after assembling according to another embodiment; 
         FIG. 7  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to another embodiment; 
         FIG. 8  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to yet another embodiment; 
         FIG. 9  illustrates a schematic view of the of the LED lamp substrate according to an embodiment; 
         FIG. 10  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to yet another embodiment; 
         FIG. 11  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to yet another embodiment; 
         FIG. 12  illustrates a schematic view of an adhesive film coating between the lamp housing and the radiator according to an embodiment; and 
         FIG. 13  illustrates a longitudinal sectional view of the lamp housing coated with the reflecting film along the central axis according to an embodiment. 
     
    
    
     DETAILED DESCRIPTION 
     In order to make the objects, technical solutions and advantages of the invention more apparent, the invention will be further illustrated in details in connection with accompanying figures and embodiments hereinafter. It should be understood that the embodiments described herein are just for explanation, but not intended to limit the invention. 
     Referring to  FIG. 1  to  FIG. 6 , an LED bulb lamp is provided according to an embodiment of this invention, wherein,  FIG. 1  illustrates a longitudinal sectional view of the LED bulb lamp along the central axis according to an embodiment;  FIG. 2  illustrates an exploded view of the LED bulb lamp according to an embodiment;  FIG. 3  illustrates a structural schematic view of the electrical isolation assembly, the LED lamp substrate and the radiator after being assembled together according to an embodiment;  FIG. 4  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to an embodiment; and  FIG. 5  illustrates an exemplary light distribution curve view of the LED bulb lamp according to an embodiment. 
     Referring to  FIG. 1  and  FIG. 2 , the LED bulb lamp comprises a lamp head  1 , a base  2 , an LED driving power supply  3 , a radiator  4 , an LED lamp substrate  5 , an electrical isolation assembly  6   a,  and a lamp housing  7 . 
     One end of the base  2  embeds into the lamp head  1 , and the other end of the base  2  embeds into one end of the radiator  4  away from the lamp housing lamp housing  7 . In one embodiment, the ends of the base  2  and the radiator  4  that are connected can be formed with lock structures such that the base can be locked with the radiator. The base  2  is with an electrical connection structure inside to enable the LED driving power supply  3  placed within the radiator  4  to electrically connect with the lamp head  1 . 
     The LED driving power supper  3  is arranged between the base  2  and the radiator  4 . The LED driving power supper  3  has input wires  31  on its end closer to the base  2  (input end). The input wires  31  are electrically connected with the lamp head  1  via the base  2 . The LED driving power supper  3  has an output wire  32  on the other end closer to the radiator  4  (output end). The output wire  32  is electrically connected with the LED lamp substrate  5 . Thus the current flows to the input wires  31  of the LED driving power supply  3  via the lamp head  1 , and then flows to the output wires  32  of the LED driving power supply  3  after voltage transformation by the LED driving power supply  3  to be supplied to the LED lamp substrate  5  to light the LED light sources  51  on the LED lamp substrate  5 . 
     In some other embodiments, several columnar bulges are disposed on the end of the LED driving power source  3  closer to the radiator  4  instead of the outputs wires  32 , the top outside surface of the columnar bulges has been conductively treated, and the columnar bulges are connected with a conductive fiberglass panel which in turn is connected with the LED lamp substrate  5  electrically. Thus, the current flows to the input wires  31  of the LED driving power supply  3  via the lamp head  1 , and then flows to the columnar bulges of the LED driving power supply  3  after voltage transformation by the LED driving power supply  3  and is supplied to the LED lamp substrate  5  via the conductive fiberglass to light the LED light sources  51  on the LED lamp substrate  5 . In these embodiments, the electrical connection of the LED driving power source  3  with the LED lamp substrate  5  can be completed by welding process, i.e., the LED lamp substrate  5  is welt on the columnar bulges of the LED driving power source  3 . 
     Next referring to  FIG. 1  and  FIG. 2 , the end of the radiator  4  away from the lamp housing  7  is embedded with the base  2 , and the end of the radiator  4  away from the lamp head  1  is connected with the LED lamp substrate  5 . Via holes  42  are formed on the radiator  4 . The via holes  42  correspond to the output wires  32  of the LED driving power supply  3 , and the output wires  32  of the LED driving power supply  3  can cross through the via hole  42  up and down. In addition, the via holes  42  also are corresponding to the via holes  52  formed on the LED lamp substrate  5  so that the output wires  32  of the LED driving power supply  3  can electrically connect with the LED lamp substrate  5  through the corresponding via holes  42  and via holes  52  in order. Further, fixing elements  43  are disposed on the end of the radiator  4  away from the lamp head  1 . The fixing elements  43  are corresponding to the fixing element  53  disposed on the LED lamp substrate  5  and the fixing element  68  disposed on the electrical isolation assembly  6   a  to enable the electrical isolation assembly  6   a  to connect with the LED lamp substrate  5  and the radiator  4 . 
     The LED lamp substrate  5  is placed on the end of the radiator  4  closer to the lamp housing  7 , and the LED lamp substrate  5  can be disposed with the electrical isolation assembly  6   a  at firstly, and then disposed on the radiator  4 . The LED lamp substrate  5  can be circularly shaped. At least one light resource  51 , which may have the traditional appearance with holder and gluey shell, chip scale package or other package structure, is mounted on the LED lamp substrate  5 . In addition, as described above, the LED lamp substrate  5  has the via holes  52  formed thereon, and the via holes  52  are corresponding to the via holes  42  on the radiator  4 . The output wires  32  of the LED driving power supply  3  can electrically connect with the LED lamp substrate  5  through the corresponding via holes  42  and via holes  52  in order. Further, as described above, the LED lamp substrate  5  has the fixing element  53  disposed thereon, the fixing elements  53  are corresponding to the fixing elements  43  on the radiator  4  and the fixing elements  68  on the electrical isolation assembly  6   a  to enable the electrical isolation assembly  6   a  to disposed on the LED lamp substrate  5  and the radiator  4 . 
     In one embodiment, the numbers of via holes  42  and the via holes  52  depends on the number of the output wires  32  of the LED driving power supply  3 , generally, these via holes can be the holes corresponding to two output wires, the anode and the cathode. If the LED driving power supply  3  has the Dimming function of adjusting the brightness of the light sources  51  or in other use cases where an increased electrical connection wires are required, the wires and the corresponding holes can be increased accordingly. 
     The electrical isolation assembly  6   a  is disposed on the LED lamp substrate  5  for isolating the charged part  54  on the LED lamp substrate  5  from outside. The electrical isolation assembly  6   a  further includes an electrical isolation unit  6 . Several through holds  67 ′ are formed on the electrical isolation unit  6 , and these through holds  67 ′ are corresponding to the through holes on the bottom portion and the LED light sources  51  on the LED lamp substrate  5  such that the light emitted from the LED light sources  51  can cross through these through holds  67 ′. When the electrical isolation assembly  6   a  is disposed on the LED lamp substrate  5 , the electrical isolation unit  6  covers the LED lamp substrate  5  for electrically isolating the charged part  54  on the LED lamp substrate  5  from outside of the LED lamp substrate  5 . In an embodiment, the electrical isolation unit  6  can be an electrical isolation board made from electrically insulating materials with high reflectivity, such as polycarbonate (PC). 
     The electrical isolation assembly  6   a  can further comprise a light processing unit  61  which can convert the outputting direction of the light emitted by the LED light sources  51 . When the electrical isolation assembly  6   a  is disposed on the LED lamp substrate  5 , the light processing unit  61  is disposed on the electrical isolation unit  6 , that is, the electrical isolation unit  6  is located between the light processing unit  61  and the LED lamp substrate  5 . The light processing unit  61  and with the electrical isolation unit  6  can be integrally formed. 
     Next, referring to  FIG. 3  and  FIG. 4 , the light processing unit  61  has a cup-shaped structure when being seen as a whole. The light processing unit  61  comprises a bottom portion  6101 , a main body  6103  and a cut top  6102 , wherein, the main body  6103  is formed between the bottom portion  6101  and the top portion  6102 . It should be understood that the light processing unit  61  is described here to include the top portion  6101 , but in fact, the top of the light processing unit  61  is hollowed out, and the boundary line just is seen from the longitudinal sectional view. In the embodiment, the preferably external diameter of the bottom portion  6101  is 16 mm˜20 mm and the preferably external diameter of the top portion  6102  is 25 mm˜29 mm. The outside surface&#39;s side boundary of the main body  6103  is approximately a straight line and has a certain angle with the extending surface of the bottom portion  6101 . In one embodiment, the angle can be 51 degree˜73 degree. It should be understood that the outside surface of the main body  6103  can also be other shapes which are good for reflecting light. 
     The electrical isolation assembly  6   a  further comprises an extending portion  66  which is extended outwardly from the circumferential of the main body  6103  and arranged to the light processing unit  61  in an encircling manner. The extending portion  66  is formed with at least one through holes  67  which are radially formed on the extending portion  66  in an encircling manner and are corresponding to the LED light sources  51  on the LED lamp substrate  5 . Accordingly, these through holds  67  are also corresponding to the through holds  67 ′ of the electrical isolation unit  6 . When the electrical isolation assembly  6   a  is disposed on the LED lamp substrate  5 , the light sources  51  on the LED lamp substrate  5  can cross through the corresponding through holes  67 ′ on the electrical isolation unit  6  and embeds into the through holes  67  of the extending portion  66 . 
     In this embodiment, the through holes  67  can be, but is not limited to, arranged evenly along the outside of the main body  6013 . The through holes  67  may have rectangle shape or circular shape, etc,. The depth of each of the through holes  67  can be equal or higher than the height of the LED light sources  51 . In one embodiment, the depth of each through hole  67  can be 100%-120% of the height of the LED light sources  51  to make sure the through holes  67  can meet the required light transmittance. In addition, the cross sectional area of each of the through holes  67  can be equal to or bigger than the bottom area of each of the LED light sources  51 . In one embodiment, the cross sectional area of the through hole  67  is 100%˜120% of the bottom area of the LED light source  51  to make sure the through hole  67  would not block the light emitted by the LED light sources  51 . 
     By the way of embedding the LED light sources  51  into the through holes  67  of the extending portion  66 , the LED light sources  51  are arranged outside the main body  6103  in an encircling manner so that the emitted light is distributed outside the main body  6103  of the light processing unit  61  when the LED light source  51  is lighting. It should be noted that, in this embodiment, a reflecting surface is formed on the outside surface of the main body  6103  to reflect the light emitted by the LED light sources  51  towards outside of the main body  6103  so that the range of the light distribution of the LED light sources  51  can be more than 180 degree. 
     As described above, the preferably external diameter of the bottom portion  6101  of the light processing unit  61  is 16 mm˜20 mm and the preferably external diameter of the top portion  6102  of the light processing unit  61  is 25 mm˜29 mm. If the external diameter of the top portion  6102  is bigger than 29 mm, a light spot will be generated on the top of the lamp housing  7  when all the LED light sources  51  on the LED lamp substrate  5  are lighting, even though the requirement of the standard for the light distribution of the LED bulb lamp can be met, the whole illumination effect of the LED bulb lamp will be affected. Further, as described before, the outside surface&#39;s side boundary of the main body  6103  has an angle of 51 degree˜73 degree with the extending surface of the bottom portion  6101 . If the angle is less than  51  degree, the whole illumination effect of the LED bulb lamp will decrease, even though the requirement of the standard for the light distribution of the LED bulb lamp can be met. 
     Referring to  FIG. 4 , fixing elements  68  are disposed on the bottom portion  6101  of the light processing unit  61  of the electrical isolation assembly  6   a.  The fixing elements  68  can cross through the electrical isolation unit  6 , and then can be fixed with the fixing elements  53  on the LED lamp substrate  5  and the fixing elements  43  on the radiator  4  to connect the electrical isolation assembly  6   a  with the LED lamp substrate  5  and then to connect with the radiator  4 . It should be understood that the electrical isolation assembly  6   a  can include the electrical isolation unit  6  only (i.e. does not includes the light processing unit  61 ), and in such case, the fixing elements  68  can be disposed on the electrical isolation unit  6 . 
     In an embodiment, each of the fixing elements  68 , the fixing elements  53  and the fixing elements  43  can be a lock structure to achieve the lock connection of the electrical isolation assembly  6   a  with the LED lamp substrate  5  and the radiator  4 . However, it should be understood that the electrical isolation assembly  6   a,  the LED lamp substrate  5  and the radiator  4  can be fixed and connected in other ways, for example, through screw or silicone connection. 
     When the electrical isolation assembly  6   a  is disposed on the LED lamp substrate  5  via the fixing elements  68 , the through holes  67  on the extending portion  66  are exactly embedded with the corresponding LED light sources  51  on the LED lamp substrate  5 . Generally, there are some charged part such as the welding points and the conductive wires on the LED lamp substrate  5  for electrically connecting the LED lamp substrate  5  to the LED driving power supply  3 , and there are some active and passive elements on the LED driving power supply  3  too. Thus, it&#39;s easy for users to contact the charged part inside the LED bulb lamp and get an electric shock accident after the lamp housing  7  is broken. In this embodiment, an electric insulation design is used for the electrical isolation unit  6 , the extending portion  66  and the fixing elements  68 , so that the whole electrical isolation assembly  6   a  can isolate the charged part on the LED lamp substrate  5  such that the charged part will not be exposed to outside even the lamp housing  7  is broken, then users will not get an electric shock accident due to contacting these charged part. 
     Back to  FIG. 1  and  FIG. 2 , the lamp housing  7  is disposed on the end of the radiator  4  away from the base  2 . And the lamp housing  7  can connect with the radiator  4  by an adhesive film. 
     An LED bulb was described above according to an embodiment of this invention. The experimental data of the distribution of luminous intensity of the LED bulb lamp according to this embodiment is as shown in  FIG. 5 . As can be seen in the  FIG. 5 , the distribution of luminous intensity of the LED bulb lamp is distributed in the scope of 0 degree˜135 degree, and 90.5% of the luminous intensity measurements (cd) have a difference with the average value of all the measurements no more than 25%, which is above the requirement of the standard (i.e., in the scope of 0 degree˜135 degree, 90% of the luminous intensity measurements (cd) have a difference with the average value of all the measurements no more than 25%). In addition, as can be seen in the  FIG. 5 , the luminous flux in the scope of 135 degree˜180 degree is 5.3%-9.5% of the total luminous flux, which is also above the requirement of the standard (the luminous flux in the scope of 135 degree˜180 degree should be no less than 5% of the total luminous flux). 
     Referring to  FIG. 6  and  FIG. 7 , an LED bulb lamp will be discussed according to another embodiment of this invention.  FIG. 6  illustrates a structural schematic view of the electrical isolation assembly, the LED lamp substrate and the radiator after assembling according to another embodiment; and  FIG. 7  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to another embodiment. 
     In the embodiment, except the electrical isolation assembly  6   b  and the LED light sources  51  on the LED lamp substrate  5  have a different arrangement with the arrangement of the electrical isolation assembly  6   a  and the light sources  51  discussed referring to  FIG. 1-5 , the other assemblies comprising the lamp head  1 , the base  2 , the LED driving power source  3 , the radiator  4 , the LED lamp substrate  5  and the lamp housing  7 , and their connection relationship can be the same with those in above embodiment. 
     To describe clearly and simply, these same assemblies are described herein briefly. One end of the base  2  embeds into the lamp head  1 , and the other end of the base  2  embeds into the end of the radiator  4  away from the lamp housing  7 . The LED driving power supply  3  is disposed inside of the base  2  and the radiator  4 . The LED driving power supply  3  has input wires  31  in one end closer to the base  2  which are electrically connected to the lamp head  1  via the base  2 . The LED driving power supply  3  has output wires  32  in the end closer to the radiator  4  which are electrically connected to the LED lamp substrate  5  via the radiator  4 . The end the of the radiator  4  away from the lamp housing  7  is embedded with the base  2 , and the other end away from the lamp head  1  connects with the LED lamp substrate  5 . The LED lamp substrate  5  is disposed on the end of the radiator  4  closer to the lamp housing  7  and the electrical isolation assembly  6   b  is disposed on the LED lamp substrate  5 . The lamp housing  7  is disposed on the end of the radiator  4  away from the base  2 . 
     The differences of the electrical isolation assembly  6   b  with the electrical isolation assembly  6   a  of the above embodiment are: the electrical isolation assembly  6   b  comprises a light processing unit  62  instead of the light processing unit  61 , and a reflecting surface is formed on inside surface of the main body  6203  of the light processing unit  62 ; the electrical isolation assembly  6   b  doesn&#39;t comprise the extending portion  66  and the through holes  67  formed on the extending portion  66 , but at least one through holes  67  corresponding to the LED light sources  51  are formed on the bottom portion  6201  of the light processing unit  62 . The LED light sources  51  on the LED lamp substrate  5  are radially arranged inside the main body  6203  in an encircling manner. The reflecting surface is formed on the inside surface of the main body  6203  of the light processing unit  62  to enable the light emitted by the LED light sources  51  is reflected towards inside of the main body  6203  to achieve the purpose of collecting light. 
     Specifically, the electrical isolation assembly  6   b  can comprises an electrical isolation unit  6 . Several through holds  67 ′ are formed on the electrical isolation unit  6 , and these through holds  67 ′ corresponding to the through holes on the bottom portion and the LED light sources  51  on the LED lamp substrate  5  such that the light emitted from the LED light sources  51  can cross through these through holds  67 ′. When the electrical isolation assembly  6   b  is disposed on the LED lamp substrate  5 , the electrical isolation unit  6  covers the LED lamp substrate  5  for electrically isolating the charged part on the LED lamp substrate  5  from outside of the LED lamp substrate  5 . Similarly, the electrical isolation unit  6  can be an electrical isolation board made from electrically insulating materials with high reflectivity, such as polycarbonate (PC). 
     Referring to  FIG. 6  and  FIG. 7 , the electrical isolation assembly  6   b  can further comprise a light processing unit  62  which can convert the outputting direction of the light emitted by the LED light sources  51 . When the electrical isolation assembly  6   b  is disposed on the LED lamp substrate  5 , the light processing unit  62  is disposed on the electrical isolation unit  6 , that is, the electrical isolation unit  6  is located between the light processing unit  62  and the LED lamp substrate  5 . Similarly, the light processing unit  62  and the electrical isolation unit  6  can also be integrally formed. 
     The light processing unit  62  has a cup-shaped structure when being seen as a whole. The light processing unit  62  comprises a bottom portion  6201 , a main body  6203  and a cut top  6202 , wherein, the main body  6203  is formed between the bottom portion  6201  and the top portion  6202 . Also, it should be understood that the light processing unit  62  is described here to include the top portion  6201 , but in fact, the top of the light processing unit  62  is hollowed out, and the boundary line just is seen from the longitudinal sectional view. In the embodiment, the preferably external diameter of the bottom portion  6201  is 37 mm˜40 mm which is the optimal size range for cooperating with the LED lamp substrate  5 . In this embodiment, a reflecting surface is formed on an inside surface of the main body  6203 , the light emitted by each of the LED light sources  51  is reflected towards inside of the main body  6203  by the reflecting surface. In an embodiment, the inside surface&#39;s side boundary of the main body  6203  is approximately a straight line and has a certain angle with the extending surface of the bottom portion  6201 . In one embodiment, the angle can be 45 degree˜75 degree to get the optimal effect of collecting light. But it should be understood that the inside surface of the main body  6203  can also be other shapes which are good for collecting light. 
     Several through holes  67  corresponding to the LED light sources  51  are formed on the bottom portion  6201  closer to the inside circumferential of the main body  6203 . It should be understood that these through holds  67  are also corresponding to the through holds  67 ′ on the electrical isolation unit  6 . The number of the through holes  67 ,  67 ′ is the same with the number of the LED light sources  51  on the LED lamp substrate  5 . In one embodiment, the preferred number of the LED light sources  51  and the through holes  67 ,  67 ′ is, but not is limited to, 4˜12. The LED light sources  51  on the LED lamp substrate  5  can cross through the corresponding through holes  67 ′ on the electrical isolation unit  6  and in turn embed into the through holes  67  on the bottom portion  6201  of light processing unit  62  when the electrical isolation assembly  6   b  is disposed on the LED lamp substrate  5 . 
     Similarly, the through holes  67  may have rectangle shape or circular shape, etc,. The depth of each of the through holes  67  can be equal to or higher than the height of the LED light sources  51 . In one embodiment, the depth of each through holes  67  can be 100%-120% of the height of the LED light sources  51 . In addition, the cross sectional area of each of the through holes  67  can be equal to or bigger than the bottom area of each of the LED light sources  51 . In one embodiment, the cross sectional area of the through hole  67  is 100%˜120% of the bottom area of the LED light source  51 . 
     By the way of embedding the LED light sources  51  into the through holes  67  formed on the bottom portion  6201 , the LED light sources  51  are arranged inside the main body  6203  in an encircling manner so that the emitted light is distributed inside the main body  6203  of the light processing unit  62  when the LED light source  51  is lighting. It should be noted that, in this embodiment, the reflecting surface is formed on the inside surface of the main body  6203  to reflect the light emitted by the LED light sources  51  towards inside of the main body  6203  so that the angle range of the light distribution of the LED light sources  51  is less than 120 degree. In addition, a condenser can be arranged in the inside of the light processing unit  62  to enhance the effect of converging light. 
     Referring to  FIG. 6  and  FIG. 7 , fixing elements  68  are disposed on the bottom portion  6201  of the light processing unit  62  by the electrical isolation assembly  6   b.  The fixing elements  68  can cross through the electrical isolation unit  6  , and then can be fixed with the fixing elements  53  on the LED lamp substrate  5  and the fixing elements  43  on the radiator  4  to connect the electrical isolation assembly  6   b  with the LED lamp substrate  5  and then to connect with the radiator  4 . Similarly, it should be understood that the electrical isolation assembly  6   a  can include the electrical isolation unit  6  only (i.e. does not includes the light processing unit  62 ), and in such case, the fixing elements  68  can be disposed on the electrical isolation unit  6 . Further, the fixing elements  68 , the fixing elements  53  and the fixing elements  43  can be a lock structure to achieve the lock connection of the electrical isolation assembly  6   b  with the LED lamp substrate  5  and the radiator  4 . The electrical isolation assembly  6   b,  the LED lamp substrate  5  and the radiator  4  can be fixed and connected in other ways, for example, through screw or silicone connection. 
     When the electrical isolation assembly  6   b  is disposed on the LED lamp substrate  5  via the fixing elements  68 , the through holes  67  are exactly embedded with the corresponding LED light sources  51  on the LED lamp substrate  5 . Generally, there are some charged part such as the welding points and the conductive wires on the LED lamp substrate  5  for electrically connecting the LED lamp substrate  5  to the LED driving power supply  3 , and there are some active and passive elements on the LED driving power supply  3  too. Thus, it&#39;s easy for users to contact the charged part in the LED bulb lamp and get an electric shock accident after the lamp housing  7  is broken. In this embodiment, an electric insulation design is used for the electrical isolation unit  6  and the fixing elements  68 , so that the whole electrical isolation assembly  6   b  can isolate the charged part on the LED lamp substrate  5  such that the charged part will not be exposed to outside even the lamp housing  7  is broken, then users will not get an electric shock accident due to contacting these charged part. 
     It should be noted that, in the two embodiments described above, according to the structure of the electrical isolation assembly  6   a  or  6   b,  the LED light sources  51  can arranged inside or outside the main body  6103 ,  6203  of the light processing unit  61 ,  62  in an encircling manner. Nevertheless, the disclosed LED bulb lamp can adopt different design. 
     An LED bulb lamp is described bellow according to another embodiment referring to  FIG. 8 .  FIG. 8  illustrates a longitudinal sectional view of the electrical isolation assembly along the central axis according to yet another embodiment. 
     In this embodiment, except the electrical isolation assembly  6   c  and the LED light sources  51  on the LED lamp substrate  5  have a different arrangement with the arrangement of electrical isolation assembly  6   a,    6   b  and the light sources  51  described in above embodiments, the other assemblies and their connection relationship can be the same with those in above embodiments and need not be repeated here. 
     The main differences of the electrical isolation assembly  6   c  with the electrical isolation assembly  6   a  and  6   b  of the above embodiment are: the electrical isolation assembly  6   c  comprises a light processing unit  63 , which has main body  6303  with non-straight camber surface, but does not have bottom portion  6301 ; the LED light sources  51  are arranged under the light processing unit  63  in an encircling manner. It should be understood that the bottom portion  6301  in the present embodiment is hollowed out, that is, there is no bottom portion  6301 . The boundary line indicated by reference number  6301  in  FIG. 8  just is shown in the longitudinal sectional view. Further, the electrical isolation unit  6  of the electrical isolation assembly  6   c  is shown lower than the bottom portion  6301 , but in fact, the electrical isolation unit  6  is located between the main body  6303  and the LED light sources  51 . Further, it should be understood that the main body  6303  may be other shape although a shape of camber surface is discussed here. 
     Specifically, a reflecting surface is formed on the outside of the camber surface of the main body  6303 . And the light processing unit  63  of the electrical isolation assembly  6   c  is above the light sources  51  on the LED lamp substrate  5  when the electrical isolation assembly  6   c  is disposed on the LED lamp substrate  5 , that is, the LED light sources  51  on the LED lamp substrate  5  are arranged under the light processing unit  63  in an encircling manner so that one part of each of the LED light sources  51  are exposed outside the main body  6303 , one part are located under the main body  6303  and the rest are exposed inside the main body  6303 .. Thus, the light emitted by the part of each of the light sources exposed outside the main body  6303  of the light processing unit  63  can be reflected by the reflecting surface on the outside surface of the main body  6303  towards outside of the main body  6303 ; the light emitted by the part of each of the light sources located under the main body  6303  of the light processing unit  63  can go towards outside along the camber surface of the main body  6303  from the bottom up due to refraction of the main body  6303 ; the light emitted by the part of each of the LED light sources exposed inside the main body  6303  of the light processing unit  63  can be outputted directly to the lamp housing  7  upwards without blocking of the bottom portion  6301 . 
     In addition, as shown in the  FIG. 8 , the fixing elements  68  can be arranged under the circumferential of the main body  6301  of the light processing unit  63  to connect the electrical isolation assembly  6   c  with the LED lamp substrate  5  and the radiator  4 . Similarly, it should be understood that the electrical isolation assembly  6   c  can include the electrical isolation unit  6  only (i.e. does not include the light processing unit  63 ), and in such case, the fixing elements  68  can be disposed on the electrical isolation unit  6 . 
     In this embodiment, due to the camber surface design of the main body  6303  of the light processing unit  63 , the design of the reflecting surface of the outside surface of the main body  6303 , and the design of the main body  6303  of the light processing unit  63  located above the LED light sources  51 , the range of the light distribution of the LED light sources can be more than 180 degree effectively. 
     As described above, the bottom portion  6301  is hollowed out and the light processing unit  63  can be arranged above the LED light sources  51  so that the light emitted by the LED light sources  51  will have the light emitting effect towards three directions after processed by the light processing unit  63 . In another embodiment, the bottom portion  6301  may be present in fact and in such case, by arranging the light processing unit  63  over the LED light sources  51  such that a part of each LED light source  51  is exposed outside the main body  6303  and another part is located under the main body  6303 , such that the light emitted by the part of each LED light source exposed outside of the main body  6303  will emits light towards two directions, and the light emitted by the part of each LED light source located under the main body  6303  will go towards outside along the camber surface of the main body  6303  from the bottom up. Thus, the light emitted by the LED light sources  51  will have the light emitting effect towards two directions after processed by the light processing unit  63 . 
     In addition, different external diameter of the bottom portion  6301  of the light processing unit  63  and the length of the extend camber surface of the main body  6303  can be designed depending on the lighting requirement for the LED bulb lamp. For example, by adjusting the external diameters of the bottom portion  6301  of the light processing unit  63  or the length of the extend camber surface of the main body  6303 , for example, the external diameter of the bottom portion  6301  is designed to be smaller to make the area of the LED light sources exposed outside the main body  6303  bigger, or the length or angle of the camber surface of the main body  6303  is designed to block more light emitted by the LED light sources, more of the light emitted by the LED light sources  51  will be reflected by the reflecting surface on the outside surface of the main body  6303 , and thus higher brightness of the reflected light can be obtained accordingly. 
     As described above, one set of LED light sources  51  are mounted on the LED lamp substrate  5  in an encircling manner in the above embodiment. In some embodiments, two sets of LED light sources can be mounted on the LED lamp substrate  5  to form two encircling arrangements, as shown in  FIG. 9 . There are two sets of LED light sources on the LED lamp substrate  5 , one set illustrated by the reference number  51  and the other set illustrated by the reference number  511 . The two sets of LED light sources  51 ,  511  are both arranged around the center of the LED lamp substrate  5  in an encircling manner, wherein, the LED light sources  511  are closer to the center of the LED lamp substrate  5  and the LED light sources  51  are closer to the edge of the LED lamp substrate  5 . Further, as shown in  FIG. 9 , the portion of the LED lamp substrate  5  mounted with the LED light sources  511  are on the LED lamp substrate  5  protrudes upward slightly as compared with the portion of the LED lamp substrate  5  mounted with the LED light sources  51  in order to be collocated with the electrical isolation assembly. 
     Referring to  FIGS. 10-11 , an LED bulb lamp deploying the arrangement with two sets of LED light sources as shown in  FIG. 9  is described.  FIG. 10  and  FIG. 11  illustrate a longitudinal sectional view of the electrical isolation assembly along the central axis according to an embodiment of this invention, respectively. 
     Firstly referring to  FIG. 10 , in this embodiment, except the electrical isolation assembly  6   d  and the LED light sources  51  on the LED lamp substrate  5  have a different arrangement with the arrangements of the electrical isolation assemblies  6   a,    6   b,    6   c,  and the light sources  51  described in the above embodiments, the other assemblies and their connection relationship can be the same with those in above embodiments and need not be repeated here. 
     In this embodiment, the electrical isolation assembly  6   d  comprises light processing unit  64 , its main body  6403  is non-straight camber surface, and its bottom portion  6401  is formed with the through holes  67  corresponding to the LED light sources  511  on the light substrate  5 . It should be noted that the electrical isolation unit  6  also is formed with corresponding through holes  67 ′. Further, it should be understood that the main body  6403  may be other shape although a shape of camber surface is discussed here. 
     In one embodiment, just an outside surface of the main body  6403  is formed with a reflecting surface. In this case, when the electrical isolation assembly  6   d  is disposed on the LED lamp substrate  5  as shown in  FIG. 9 , the first set of LED light sources  51  are arranged inside the main body  6403  in an encircling manner, and the light emitted by the first set of light sources  511  can cross through the through holes  67 ′ and the through holes  67  formed on the electrical isolation unit  6  and the bottom portion  6403  correspondingly and are outputted to the lamp housing  7  directly. In addition, the second set of light sources  51  are under the light processing assembly  64  so that one part of each LED light source in this set are exposed outside main body  6403  of the light processing assembly  64  and one part are located under the main body  6403 . Then the light emitted by the part of each LED light sources  51  exposed outside the main body  6403  of the light processing unit  64  is reflected by the reflecting surface towards outside of the main body  6403 ; the light emitted by the part of each LED light sources located under the main body  6403  goes toward outside along the camber surface of the main body  6403  from the bottom up. 
     It should be understood that both the inside and outside surface of the main body  6403  can be formed with a reflecting surface. In such case, as above, for the first set of light sources  51  located under the light processing unit  64 , the light emitted by the part of each of the light sources  51  exposed outside the main body  6403  of the light processing unit  64  is reflected by the reflecting surface on the outside surface of the main body  6403  towards outside of the main body  6403 , and the light emitted by the part of the light sources  51  located under the main body  6403  of the light processing unit  64  goes toward outside along the camber surface of the main body  6403  from the bottom up. Meanwhile, for the LED light sources  511  arranged inside the main body  6403  in an encircling manner, the light emitted by each of the light sources  511  is reflected by the reflecting surface on the inside surface of the main body  6403  towards inside of the main body  6403 . This arrangement can bring another illumination effect. 
     In addition, it is possible that only an inside surface of the main body  6403  can be formed with a reflecting surface. In this case, for the LED light sources  511  arranged inside the main body  6403  in an encircling manner, the light emitted by each of the light sources  511  emit to the lamp housing directly. Meanwhile, for the light sources  51  located under the light processing unit  64 , the light emitted by each of the light sources  511  goes toward outside from the bottom up along the camber surface of the main body  6403 . This arrangement can bring yet another illumination effect. 
     Referring to  FIG. 12 , another embodiment of the LED bulb lamp deploying the arrangement with two sets of LED light sources as shown in  FIG. 9  is described. 
     The electrical isolation assembly  6   e  comprises light processing unit  65 , the side surface&#39;s side boundary of its main body  6503  is straight line, and its bottom portion  6503  is formed with the through holes  67  corresponding to the LED light sources  511  on the LED lamp substrate  5 . In addition, the electrical isolation assembly  6   e  further comprises extending portion  66  which is formed with the through holes  67  corresponding to the LED light sources  51  on the LED lamp substrate  5 . The LED light sources  51 ,  511  can be arranged inside and outside the main body  6403  of the light processing unit  64  in an encircling manner at the same time. It should be noted that the electrical isolation unit  6  also is formed with corresponding through holes  67 ′, and these through holes  67 ′ are also corresponding to those disposed on the extending portion  66  and on the bottom portion  6501 . Further, it should be understood that the main body  6503  may be other shape although it is discussed here with straight boundary line of its side surface. 
     In an embodiment, a reflecting surface is just formed on an outside surface of the main body  6503 . In this case, when the electrical isolation assembly  6   e  is disposed on the LED lamp substrate  5  as shown in  FIG. 10 , the first set of LED light sources  51  are arranged inside the main body  6503  in an encircling manner, and the light emitted by the first set of light sources  511  can cross through the through holes  67 ′ and the through holes  67  formed on the electrical isolation unit  6  and the bottom portion  6503  correspondingly and are outputted to the lamp housing  7  directly. In addition, the second set of light sources  51  are arranged outside the main body  6503  in an encircling manner, and the light emitted by the light sources  51  is reflected by the reflecting surface on the outside surface of the main body  6503  towards outside of the main body  6503 . 
     It should be understood that both inside and outside surface of the main body  6503  can be formed with a reflecting surface. In such case, for the LED light sources  511  arranged inside the main body  6503  in an encircling manner, the light emitted by each of the light sources  511  is reflected by the reflecting surface on the inside surface of the main body  6503  towards inside of the main body  6503 . Meanwhile, for the light sources  51  arranged outside the main body  6503  in an encircling manner, the light emitted by the light sources  51  is reflected by the reflecting surface on the inside surface towards outside of the main body  6503 . This arrangement can bring another illumination effect. 
     In addition, it is possible that only an inside surface of the main body  6503  can be formed with a reflecting surface. In this case, for the LED light sources  511  arranged inside surface the main body  6503  in an encircling manner, the light emitted by the light sources  511  is reflected by the reflecting surface on the inside surface of the main body  6503  towards inside of the main body  6503 . Meanwhile, for the light sources  51  arranged outside the main body  6503  in an encircling manner, the light emitted by the light sources  51  goes towards outside from the bottom up along the straight side surface of the main body  6503 . This arrangement can bring yet another illumination effect. 
     In the above arrangements, the emitting direction of the light outside the main body  6503  can be adjusted by changing the design of the angle of the inside or outside surface of the main body  6503  with the extending surface of the bottom portion  6501 . 
     It should be noted that the electrical isolation assembly  6   d,    6   e  in the above embodiments can be the same as the electrical isolation assembly  6   b  with the fixing elements  68  arranged under the bottom portion  6401 ,  6501  of the light processing unit  64 ,  65  to connect the electrical isolation assembly  6   d,    6   e  with the LED lamp substrate  5  and the radiator  4 . Similarly, in the case of the electrical isolation assembly  6   a  includes only the electrical isolation unit  6  (i.e. it does not include the light processing unit  64 ,  65 ), the fixing elements  68  can be disposed on the electrical isolation unit  6 . The fixing elements  68  can employ the lock structure to achieve the lock connection. 
     When the electrical isolation assembly  6   d,    6   e  is disposed on the LED lamp substrate  5  by the fixing elements  68 , the through holes  67  on the bottom portion  6403  and the through holes  67  on the extending portion  66  can be embedded with the two sets of light sources  51  on the LED lamp substrate  5  correspondingly. As the above embodiment, the electrical isolation unit  6 , the extending portion  66  and the fixing element  68  can employ an electrical insulation design. Thus, the whole electrical isolation assembly  6   d,    6   e  can cover the charged part on the LED lamp substrate  5  such that the charged part would not expose to the outside even though the lamp housing  7  is broken, so users can be protected from contacting the charged part to avoid an electric shock accident. 
     In addition, it should be understood that the electrical isolation unit  6 , the light processing unit  61 / 62 / 63 / 64 / 65 , the extending portion  66  and the fixing elements  68  can be integrally formed. They can be made of PC plastic materials having the reflectivity more than 92% or metal materials with high reflectivity by plating processing. 
       FIG. 12  illustrates a schematic figure of adhesive film coating between the lamp housing and the radiator according to an embodiment. In the above described embodiments, a layer of adhesive film can be coated on the inside or outside surface of the lamp housing  7  or between the lamp housing  7  and the radiator  4  to isolate the outside of the lamp housing  7  from the inside when the lamp housing is broken. 
     The main ingredient of the adhesive film  8  is calcium carbonate or strontium orthophosphate that can collocate with organic solvents to blend appropriately. In one embodiment, the adhesive film  8  consists of vinyl-terminated silicon oil, hydrosilicon oil, dimethylbenzene and calcium carbonate. 
     Dimethylbenzene is a supporting material among these ingredients, which volatilizes when the adhesive film has been coated on the inside or outside surface of the lamp housing  7  and has been solidified, and the main function of dimethylbenzene is to adjust viscosity so as to adjust the thickness of the adhesive film. 
     The thickness selection of the adhesive film  8  is related to the total weight of the LET bulb lamp. The thickness of the adhesive film  8  could be between 200 μm˜300 μm when the radiator  4  is injected by heat conducting glue (casting glue) (consisting of at least 70% of the heat conducting glue which is 0.7˜0.9 W/m*K) and the total weight of the LED bulb lamp is more than 100 g. 
     The total weight of the LED bulb lamp is less than about 80 g when there is no heat conducting glue being injected into the radiator  4 , and the thickness of the adhesive film  8  can be 40 μm˜90 μm so that the LED bulb lamp could have the ability of anti-explosion. The lower limit of the thickness is related to the total weight of the LED bulb light but the question of anti-explosion should be considered, whereas the light transmittance will not be enough and the cost of materials will be increased if the upper limit is more than 300 μm. 
     When the lamp housing  7  is broken, the adhesive film  8  will join the fragments of the lamp housing  7  together to avoid forming a hole throughout the inside and the outside of the lamp housing  7 , so that protecting user from contacting the charged part inside the lamp housing  7  to avoid electric shock accidents. 
     In addition, the LED bulb lamp according to the disclosure can be selectively coated with a layer of diffusion film on the inside or the outside surface of the lamp housing  7  to mitigate the granular sensation of user watching the light sources  51 . Further, the diffusion film not only has the function of diffusing light but also has the function of electrical isolation so as to reduce the risk of electric shock when the lamp housing  7  is broken. In addition, the diffusion film can enable the light to be diffusing to all direction when the LED light sources is lighting, and avoiding generating a dark area on the top of the lamp housing  7  to make a more comfortable lighting environment. 
     The main ingredients of the diffusion film can comprise at least one or combination of calcium carbonate, calcium halophosphate and aluminum oxide. The diffusion film could have optimal effect of light diffusion and transmission (more than 90% in some cases) when formed by calcium carbonate with an appropriate solution. In an embodiment, the ingredients of the diffusion film comprise: calcium carbonate (e.g., CMS-5000, white powder), thickener (e.g., thickener DV-961, milky white liquid), and ceramic activated carbon (e.g., ceramic activated carbon SW-C, colorless liquid). The chemical name of the thickener DV-961 is colloidal silica modified acrylic resin which is used to increase the stickiness when the calcium carbonate is coated on the inside or outside surface of the lamp housing  7  and comprises the ingredients of acrylic resin, silicone gel and pure water. 
     In one embodiment, the diffusion film adopts calcium carbonate as the main ingredient and collocates with thickener, ceramic activated carbon and deionizer water. These ingredients are coated on the inside or outside surface of the lamp housing  7  after blending, and the average coat thickness is in the range of 20 μm˜30 μm. The deionizer water will volatilize at last and only the three ingredients of calcium carbonate, thickener, and ceramic activated carbon left. In an embodiment, if the diffusion film is formed with different ingredients, the thickness range of the diffusion film can be adopted is 200 μm˜300 μm and the light transmittance is kept in the range of 92%˜94%, which will have a different effect. 
     In other embodiments, calcium halophosphate and aluminum oxide can be selected as the main ingredients of the diffusion film. The particle size of calcium carbonate is in the range of about 2 μm˜4 μm, whereas the particle sizes of calcium halophosphate and aluminum oxide are in the ranges of about 4 μm˜6 μm and 1 μm˜2 μm respectively. When the required range of light transmittance is 85%˜92%, the average thickness of the diffusion film which has the main gradient of calcium carbonate in whole is about 20 μm˜30 μm; the average thickness of the diffusion film which has the main gradient of calcium halophosphate is 25 μm˜35 μm and the average thickness of the diffusion film which has the main gradient of aluminum oxide is 10 μm˜15 μm when requiring the same light transmittance. If requiring a higher light transmittance, for example, more than 92%, the required thickness of the diffusion film which has the main ingredient of calcium carbonate, calcium halophosphate and aluminum oxide should be thinner. For example, the required thickness of the diffusion film which has the main ingredient of calcium carbonate should be within 10 μm˜15 μm. That is, the main ingredients and the corresponding formed thickness, or the like, of the diffusion film to be coated can be selected based on the usage occasion of the LET bulb lamp which has different requirement of light transmittance. 
     In addition, the LED bulb lamp of present disclosure can be selectively coated with a thin layer of reflecting film on the inside top surface of the lamp housing  7  to convert a portion of the light outputting towards the top of the lamp housing  7  by LED light sources  51  to the sidewall. The reflecting film may have the main gradient of barium sulfate and may be mixed with thickener, 3% of ceramic activated carbon and deionizer water. In an embodiment, the concentration of barium sulfate can be in the range of 45%-55%, and the thickness of the formed reflecting film  9  is about 20 μm˜30 μm at this moment. When the average thickness of the coated reflecting film  9  is about 17 μm˜20 μm, the light transmittance is up to about 97˜98%, that is, 2% of the light emitting towards topside could be reflected towards the sidewall of the LED bulb lamp. 
     It&#39;s to be noted that the target of coating reflecting film  9  is to generate reflection effect after the light hitting the barium sulfate particles, thus there is no need to coat the total lamp housing  7  with the reflecting film  9 . As shown in  FIG. 13 , taking the central axis which is from the lamp head  1  to the center of the lamp housing  7  as the center, the reflecting film  9  can be coated on an approximate equal area from the central axis, that is, the coated reflecting film is distributed symmetrically along the central axis as a circular curved surface, and the coated t reflecting film within an area which has a certain angle with the central axis. In an embodiment, the angle can be 0degree˜60 degree. Preferably, the angle can be 0 degree˜45 degree. In addition, when the concentration of the selected reflecting film solution is higher, the coated reflecting film  9  need not to be too thick. Of course, if the requirement for the light transmittance is just 95%, that is, 5% of the light emitting upward will be reflected towards the sidewall of the LED bulb lamp, an adoptable concentration of the barium sulfate solution can be about 55%˜60%, and the layer thickness of the reflecting film can be in the range of 25 μm˜30 μm. Further, due to on the top of the lamp housing, the light luminance of the light distributed within the area where the angle with the central axis is 0 degree˜60 degree is diminishing from 0 degree to 60 degree, so the layer thickness of the reflecting film can be gradually reduced from 0 degree at which the thickness is biggest to 60 degree at which the thickness is smallest. 
     It should be understood that the above described embodiments are merely preferred embodiments of the invention, but not intended to limit the invention. Any modifications, equivalent alternations and improvements, or any direct and indirect applications in other related technical field that are made within the spirit and scope of the invention described in the specification and the figures should be included in the protection scope of the invention.