Simulated flame lamp
Technical Field
The utility model relates to an emulation flame lamp especially relates to an emulation flame lamp that simulation flame combustion effect and emulation effect are good.
Background
Most of the existing simulated flame lamps simulate the flame combustion state by driving a flame sheet or a flame bulb shell to swing, so that a certain simulation effect can be achieved, but the simulation effect is not ideal. The reason is that the flame has both dynamic effect and color effect when the real flame burns, and the simulation mode in the prior art usually only focuses on simulating the dynamic effect but neglects the fidelity brought by the color effect. For example, the flame of the existing simulated flame lamp is often simulated to be monochromatic and generally yellow, however, when the flame is actually burnt, the flame is blue near the flame center and yellow far from the flame center, and the flame is actually two-color, so the simulation effect of the monochromatic flame of the existing simulated flame lamp is not ideal.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a simulation flame lamp that simulation flame combustion effect and simulation effect are good.
In order to achieve the above object, the utility model provides an emulation flame lamp includes bulb shell, pedestal, first luminous body, second luminous body, division board and power, the bulb shell is located on the pedestal, the division board set up in will in the bulb shell divide into first inner chamber and second inner chamber, first luminous body set up in the upper surface of division board is located first inner chamber, the second luminous body set up in the bottom surface of division board is located the second inner chamber, first luminous body and second luminous body with the power electricity is connected, the power set up in the pedestal.
Compared with the prior art, because the utility model discloses set up the division board in the bulb shell, will the bulb shell falls into first inner chamber and second inner chamber, again in first inner chamber sets up first luminous body set up the second luminous body in the second inner chamber, send the light of different colors and/or intensity through controlling first luminous body and second luminous body to, separate these two kinds of light through the division board, avoid the light of a color of below to influence the light of another kind of color of top, thereby the upper and lower extreme of the bulb shell that makes forms double-colored, and then can highly imitate the effect of real flame burning on the color, the simulation effect is very good.
Preferably, the artificial flame lamp further comprises a conductive pin, the conductive end of the first light emitter is electrically connected with the conductive pin, and the conductive pin extends out of the bulb shell and into the base body to be electrically connected with the power supply. The conductive pins can be used for electrically connecting the first light emitter and a power supply, and can also be used for supporting the first light emitter, the isolation plate and the bulb shell.
Specifically, the isolation plate is provided with a through hole through which the conductive pin or the conductive end of the first light emitter passes.
Specifically, the isolation plate is provided with a conductive terminal, the conductive end of the second light-emitting body is connected with the conductive terminal, and the conductive terminal is electrically connected with the conductive pin. This enables the second light emitter to be electrically conductive also through the conductive terminals.
Specifically, the simulated flame lamp further comprises a sleeve, the sleeve is sleeved outside the conductive pins, and part of the sleeve is arranged between the base and the bulb shell in an exposed mode. . The sleeve can protect the conductive pins and can form a lamp wick between the base body and the bulb shell, so that the simulation effect is further improved.
Preferably, the simulated flame lamp further comprises a control circuit board, wherein the control circuit board is arranged in the base body and is electrically connected with the power supply, the first light emitter and the second light emitter.
Specifically, a lamp cap is arranged in the base body, and the control circuit board is arranged in the lamp cap.
Specifically, the base body comprises a main body and a power supply cover, wherein the power supply cover is arranged at the lower end of the main body and is in threaded connection with the main body.
Specifically, a first conducting strip and a second conducting strip are arranged in the base body, one end of the first conducting strip is connected with the output end of the control circuit board, the input end of the control circuit board is electrically connected with a first electrode of the power supply, the other end of the first conducting strip is electrically connected with the second conducting strip, and the second conducting strip is fixed on the inner side of the power supply cover, so that when the power supply cover is screwed on the main body, the first conducting strip is conducted with a second electrode of the power supply. Through setting up first conducting strip and second conducting strip, the power lid only need screw up or unscrew in the main part can be switched on or cut off the power supply to control circuit board, and then realizes the function of switch, simple structure, convenient to use.
Preferably, the isolation plate is transversely disposed in the bulb shell, so that the first inner cavity and the second inner cavity are vertically distributed. The first inner cavity and the second inner cavity are distributed up and down, so that the upper part and the lower part of the bulb shell can present different light colors, and the flame simulation effect is further improved.
Drawings
Fig. 1 is a structural diagram of the artificial flame lamp of the present invention.
Fig. 2 is an exploded view of the simulated flame lamp of the present invention.
Fig. 3 is a cross-sectional view of the bulb shell of the artificial flame lamp of the present invention.
Detailed Description
In order to explain technical contents, structural features, and effects achieved by the present invention in detail, the following description is given in conjunction with the embodiments and the accompanying drawings.
As shown in fig. 1, fig. 2 and fig. 3, the simulated flame lamp 100 of the present invention includes a lamp bulb 1, a lamp holder 2, a base 3, a first light emitter 4, a second light emitter 5, a partition board 6, a control circuit board 7 and a power supply 8, wherein the lamp holder 2 is disposed in the base 3, the control circuit board 7 is disposed in the base 3, and more preferably, the control circuit board 7 is disposed in the lamp holder 2; the bulb shell 1 is connected to the lamp holder 2 and is exposed out of the upper end of the base body 3; the base body 3 is formed in the shape of a candle. The isolating plate 6 is arranged in the bulb shell 1 to divide the bulb shell 1 into a first inner cavity 11 and a second inner cavity 12, and specifically, the isolating plate 6 is transversely arranged in the bulb shell 1 to enable the first inner cavity 11 and the second inner cavity 12 to be vertically distributed. The first luminous body 4 is arranged on the upper surface of the isolation plate 6 and positioned in the first inner cavity 11, the second luminous body 5 is arranged on the bottom surface of the isolation plate 6 and positioned in the second inner cavity 12, the first luminous body 4 can emit yellow light, and the second luminous body 5 can emit blue light. The first inner cavity 11 and the second inner cavity 12 are distributed up and down, so that the upper part and the lower part of the bulb shell 1 can present different colors, and the flame simulation effect is further improved. The first luminous body 4 and the second luminous body 5 are electrically connected with the control circuit board 7, the control circuit board 7 can control the lighting, the extinguishing of the first luminous body 4 and the second luminous body 5, the intensity of light and the like, the control circuit board 7 is electrically connected with the power supply 8, the power supply 8 is arranged in the base body 3, and the lamp holder 2 and the power supply 8 are arranged along the axial direction of the base body 3.
As shown in fig. 2 and fig. 3, specifically, the simulated flame lamp 100 further includes at least two conductive pins 9, the positive conductive end of the first light emitter 4 is electrically connected to one of the conductive pins 9, the negative conductive end of the first light emitter 4 is electrically connected to the other conductive pin 9, and the conductive pins 9 and the conductive end of the first light emitter 4 may be in a split structure or an integrally formed structure. The isolation plate 6 is provided with at least two through holes 61 for the conductive pins 9 or the conductive ends of the first light emitter 4 to pass through, and each through hole 61 is used for one conductive pin 9 to pass through so as to isolate the two electrodes. In the present application, the conductive pins 9 extend out of the bulb shell 1 and into the lamp holder 2, and are electrically connected with the power supply 8 through the control circuit board 7; meanwhile, the conductive pins 9 are made of a hard material, so that the first light emitter 4 and the bulb shell 1 can be supported by the conductive pins 9. Therefore, the conductive pins 9 may serve to electrically connect the first light emitter 4 and the power supply 8, and may also serve to support the first light emitter 4, the isolation plate 6, and the lamp case 1. The bottom surface of the isolation plate 6 is provided with at least two conductive terminals, the positive and negative conductive ends of the second luminous body 5 are correspondingly connected with the conductive terminals one by one, and each conductive terminal is electrically connected with each conductive pin 9 in a one-to-one correspondence manner. This enables the second luminous body 5 to be electrically conductive also via the electrically conductive terminals.
Referring to fig. 1 and 2, the simulated flame lamp 100 further includes a sleeve 110, the sleeve 110 is sleeved outside the conductive pins 9, and a portion of the sleeve 110 is disposed between the base 3 and the lamp bulb 1 in an exposed manner. The outer surface of the sleeve 110 is black, and the sleeve 110 can protect the conductive pins 9 and form a black wick between the base body 3 and the bulb shell 1, so as to further improve the simulation effect.
As shown in fig. 2, the base 3 includes a main body 31 and a power cover 32, and the power cover 32 is disposed at a lower end of the main body 31 and is in threaded connection with the main body 31. A first conductive sheet 33 and a second conductive sheet 34 are arranged in the base body 3, one end of the first conductive sheet 33 is connected with the output end of the control circuit board 7, the input end of the control circuit board 7 is electrically connected with the first electrode of the power supply 8, the other end of the first conductive sheet 33 is electrically connected with the second conductive sheet 34, and the second conductive sheet 34 is fixed on the inner side of the power supply cover 32, so that when the power supply cover 32 is screwed on the main body 31, the first conductive sheet 33 is conducted with the second electrode of the power supply 8. Through setting up first conducting strip 33 and second conducting strip 34, power cover 32 only need screw up or unscrew in main part 31 can be switched on or cut off the power supply to control circuit board 7, and then realizes the function of switch, simple structure, convenient to use. The lower end of the main body 31 is provided with a tray 120, the tray 120 supports the seat body 3, the lower end of the tray 120 is provided with a clip 130, and the clip 130 is used for positioning the seat body 3.
Compared with the prior art, because the utility model discloses set up division board 6 in the bulb shell 1, will bulb shell 1 falls into first inner chamber 11 and second inner chamber 12, again first inner chamber 11 sets up first luminous body 4 set up second luminous body 5 in the second inner chamber 12, sends yellow and blue light through controlling first luminous body 4 and second luminous body 5 to, separate these two kinds of light through division board 6 and come, avoid the light of a color of below to influence the light of another kind of color of top, thereby the upper and lower extreme of bulb shell 1 that makes forms the bluish double-colored, and then can highly imitate the effect of real flame burning on the color, and the simulation effect is very good.
The above disclosure is only a preferred embodiment of the present invention, and certainly, the scope of the present invention should not be limited thereto, and therefore, the scope of the present invention is not limited to the above embodiments.