The invention relates to a downlight fixing structure. More particularly, it relates to a downlight fixing structure having springs.
Traditional downlights have two spring fixing structures on two sides. Each spring fixing structure is axially pressed and placed in an inverse T slot. This technique has been applied in the industry for many years. The existing problem is that the installation of the spring fixing structure is complex and can only be processed by human hands, which leads to low productivity. On the other hand, an end of the spring fixing structure can get loose and slide out of the inverse T slot during an installation process because of unbalanced forces. Thus, it is in great need as to how to design a new downlight fixing structure that can have the fixing function of a spring and also can be installed by automatic machine.
One objective of the invention is to provide a downlight fixing structure in which springs can be easily inserted and locked.
Another objective of the invention is to provide a downlight fixing structure in which springs can be installed by an automatic machine.
According to one aspect of the invention, a downlight fixing structure is provided. The downlight fixing structure comprises a housing and a spring. The housing is for accommodating light components. The housing has an insertion lock structure on a side of the housing. The spring comprises a coil portion, a head portion, and a tail portion. The coil portion, the head portion and the tail portion are formed by the same metal wire. The head portion is inserted into the insertion lock structure.
According to another aspect of the invention, a downlight fixing structure is provided. A downlight fixing structure comprises a housing, a spring cover, and a spring. The housing is for accommodating light components. The spring cover is located on a side of the housing. The spring cover has a conduit with a top opening and a bottom opening. The spring cover comprises a snap-fit component below the bottom opening. The spring comprises a coil portion, a head portion, and a tail portion. The head portion is inserted into the conduit. The snap-fit component locks the head portion.
The insertion lock structure 106 and the insertion lock structure 107 are located on both sides of the housing 105. In the embodiment, the insertion lock structure 106 and the insertion lock structure are symmetrically located on both sides of the housing 105. The spring 101 comprises a coil portion 108, a head portion 103, and a tail portion 104. In some embodiments, a length of the tail portion 104 is longer than a length of the head portion 103. The head portion 103 and the tail portion 104 have a rectangular shape. The coil portion 108, the head portion 103, and the tail portion 104 are formed by the same metal wire. In this embodiment, the housing 105 is made of plastic material. In some embodiments, the housing 105 is made of metal.
An end of the head portion 103 of the spring 101 extends into an inner space of the coil portion 108 from one side of the coil portion 108, and the other end of the head portion 103 is connected to the coil portion 108 in a continuous form. An end of the tail portion 104 extends into the inner space of the coil portion 108 from the other side of the coil portion 108, and the other end of the tail portion 104 is connected to the coil portion 108 in a continuous form. In some embodiments, the length of the end of the head portion 103 extending into the coil portion 108 can reach 5 mm. The length of the end of the tail portion 104 extending into the coil portion 108 can reach 5 mm. The angle between the plane formed by the head portion 103 and that formed by the tail portion 104 is an acute angle.
When the head portion 103 and the tail portion 104 are pulled open, there is a resilient force tending to get the head portion 103 and the tail portion 104 back to the normal angle. The resilient force can help to fix the downlight onto a ceiling or a wall. With reference to
In some embodiments, the raised part 111 forms a hook or barb structure to hold the head portion 103 more securely. In some embodiments, there are slit openings on lateral sides and a bottom side of the raised part 111. That is, there are vertical slit openings on the lateral sides and a horizontal opening on the bottom side of the raised part 111.
The vertical slit openings 112 and the horizontal slit opening 113 can make the raised part 111 more resilient because they allow a greater degree of bending of the raised part 111. In some embodiments, the width of the vertical slit openings 112 is preferably 1mm and the width of the horizontal slit opening 113 is preferably 2mm. In some embodiments, the raised part 111 does not have vertical slit openings 112. In some embodiments, the raised part 111 does not have a horizontal slit opening 113. In some embodiments, the raised part 111 is a part of the housing 105. The raised part 111 and the housing 105 are formed integrally using the same materials.
The raised part 111 is resilient, so the head portion 103 of the spring 101 can be inserted into the insertion lock structure 106 by an automatic machine. In this way, the cost of labor is saved.
The spring cover 30 is a flat piece or a thin piece with small curvature. The spring cover 30 has a sunken part 302. The sunken part 302 is a part of the spring cover 30 and is formed integrally with the spring cover 30. The sunken part 302 has a top opening and a bottom opening. The sunken part 302 forms a conduit 301 with the two openings. A snap-fit component 303 is located at a lower position of the spring cover 30. The snap-fit component 303 is near the bottom opening. The spring cover 30, the sunken part 302, and the snap-fit component 303 are formed integrally. The spring 20 comprises a coil portion 208, a head portion 203, and a tail portion 204. The head portion 203 and the tail portion 204 have a rectangular shape. The head portion 203 and the tail portion 204 are formed by the same metal wire that forms the coil portion 208.
In some embodiments, the length of the tail portion 204 is longer than that of the head portion 203. The coil portion 208, the head portion 203, and the tail portion 204 are formed by the same metal wire. An end of the head portion 203 extends into an inner space of the coil portion 208 from an end of the coil portion 208. The other end of the head portion 203 is connected to the coil portion 208 in a continuous form.
An end of the tail portion 204 extends into the inner space of the coil portion 208 from the other end of the coil portion 208. The other end of the tail portion 204 is connected to the coil portion 208 in a continuous form. The head portion 203 of the spring 20 is inserted into the conduit 301 and is locked by the snap-fit component 303. In this way, the head portion 203 is locked in position in the conduit 301. The head portion 203 does not get loose or slide out of the conduit 301.
With reference to
With reference to
In this manner, the snap-fit component 303 is flexible and resilient. When the front end 2031 of the head portion 203 reaches the lower part of the snap-fit component 303, the front end 1031 of the head portion 203 directly locks into a space under the snap-fit component 303 because the snap-fit component 303 is flexible and resilient. Therefore, the head portion 203 of the spring 20 is locked by the snap-fit component 303 without getting loose or sliding out.
With reference to
Therefore, the head portion 203 of the spring 20 is locked by the snap-fit component 303 without getting loose or sliding out. In some embodiments, the snap-fit component 303 forms a hook or barb structure to hold the head portion 203 more securely. In a production process, the head portion 203 of the spring 20 can be inserted into the conduit 301 of the spring cover 30 by an automatic machine, so automation of production can be realized.
Number | Date | Country | Kind |
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201710277621.8 | Apr 2017 | CN | national |