CN217936034U - Barrier lamp control device - Google Patents

Abstract

The embodiment of the utility model discloses barrier lamp controlling means, the device includes: the remote lamp effect control unit generates a remote pulse signal and transmits the remote pulse signal to the first main control unit; the trigger key generates a trigger signal and sends the trigger signal to the first main control unit; the first main control unit transmits the remote pulse signal to the second main control unit when receiving the trigger signal; the second main control unit stores the remote pulse signal and sends the remote pulse signal to the driving unit; the driving unit amplifies the remote pulse signal into a display signal and sends the display signal to the light-emitting component; the light emitting component generates a light source according to the display signal. The embodiment of the utility model provides a device can realize that offshore platform uses the barrier lamp of same kind of model, practices thrift the cost, reduces field operation's risk, and high-efficient ground carries out remote control and debugging to the barrier lamp in a flexible way.

Description

Barrier lamp control device

Technical Field

The embodiment of the utility model provides a relate to barrier lamp control technical field, especially relate to a barrier lamp control device.

Background

At least two types of barrier lamps are required to be installed on the offshore platform, one type of barrier lamp is installed at the highest position of the platform and plays a role in prompting aerial flight machinery such as airplanes and the like, and the other type of barrier lamp is also called an aviation barrier lamp; the other is mounted at the edge of the platform, for example, at the four corners, for warning nearby passing ships that there are obstacles, also called navigation lights.

In the related art, for a barrier lamp of a fixed model, an independent control box is required to control the barrier lamp, the function of the barrier lamp is single, and the barrier lamp can only be used in a specific place, so that the flexibility and the universality are poor.

SUMMERY OF THE UTILITY MODEL

An embodiment of the utility model provides a barrier lamp controlling means can realize that offshore platform uses the barrier lamp of same kind of model, practices thrift the cost, reduces field operation's risk, carries out remote control and debugging to the barrier lamp high-efficiently in a flexible way.

The embodiment of the utility model provides a barrier lamp control device, which comprises a remote lamp effect control module and a barrier lamp; wherein:

the remote lamp effect control module comprises a remote lamp effect control unit, a first main control unit, a wireless transmitting unit and a trigger key; the barrier lamp comprises a wireless receiving unit, a second main control unit, a driving unit and a light-emitting assembly;

the first main control unit is respectively connected with the remote lamp effect control unit, the trigger key and the wireless transmitting unit; the second main control unit is respectively connected with the wireless receiving unit and the driving unit, and the driving unit is connected with the light-emitting assembly; the wireless transmitting unit is connected with the wireless receiving unit;

the remote lamp effect control unit generates a remote pulse signal and transmits the remote pulse signal to the first main control unit;

the trigger key generates a trigger signal and sends the trigger signal to the first main control unit;

the first main control unit transmits the remote pulse signal to the second main control unit through the wireless transmitting unit and the wireless receiving unit in sequence when receiving the trigger signal;

the second main control unit stores the remote pulse signal and sends the remote pulse signal to the driving unit;

the driving unit amplifies the remote pulse signal into a display signal and sends the display signal to the light-emitting component; the display signal comprises at least one of an energy signal, an intensity signal, a color signal, a flicker signal and a flicker period signal;

the light-emitting component generates a light source according to the display signal.

Optionally, the remote light effect control unit includes at least one dial switch combination; the dial switch combinations are arranged according to a preset function sequence; the dial switch combination comprises: the first dial switch combination is used for generating an energy pulse signal; the second dial switch combination is used for generating an intensity pulse signal; the third dial switch combination is used for generating a color pulse signal; the fourth dial switch combination is used for generating a flicker pulse signal; and the fifth dial switch combination is used for generating a flicker time pulse signal.

Optionally, the first toggle actuator assembly includes a first toggle actuator, and is specifically configured to: when the first dial switch is located at a first position, the energy utilization pulse signal is an energy-saving pulse signal; or when the first dial switch is located at the second position, the energy utilization pulse signal is a normally bright pulse signal.

Optionally, the second toggle assembly includes two second toggle switches, and is specifically configured to: when all the second dial switches are located at the first position, the strength pulse signal is a high strength pulse signal; or when all the second dial switches are located at the second position, the strength pulse signal is a non-strength pulse signal; or when the first second dial switch is located at the first position and the second dial switch is located at the second position, the strength pulse signal is a medium strength pulse signal; or when the first second dial switch is located at the second position and the second dial switch is located at the first position, the strength pulse signal is a low-strength pulse signal.

Optionally, the third toggle assembly includes two third toggle assemblies, which are specifically configured to: when all the third dial switches are positioned at the first position, the color pulse signal is a red pulse signal; or when all the third dial switches are located at the second position, the color pulse signal is a white pulse signal; or when the first third dial switch is located at the first position and the second third dial switch is located at the second position, the color pulse signal is a green pulse signal; or when the first third dial switch is located at the second position and the second third dial switch is located at the first position, the color pulse signal is a yellow pulse signal.

Optionally, the fourth toggle actuator combination includes two fourth toggle actuators, and is specifically configured to: when all the fourth dial switches are located at the first position, the flicker pulse signals are irregular flicker pulse signals; or when all the fourth dial switches are located at the second position, the flicker pulse signals are regular flicker pulse signals; or when one fourth dial switch is located at the first position and the other fourth dial switch is located at the second position, the flicker pulse signal is a normally bright pulse signal.

Optionally, the fifth dip switch combination includes 8 fifth dip switches, and the fifth dip switches are configured to determine a flashing period and perform flashing timing when all the fourth dip switches are located at the second position; or the fifth dial switch is used for carrying out flicker timing according to a Morse code meter when all the fourth dial switches are positioned at the first position.

Optionally, the remote lamp effect control module further includes a display unit connected to the first main control unit; the first main control unit is also used for sending the remote pulse signal to the display unit; and the display unit is used for displaying a setting result to a user when receiving the remote pulse signal.

Optionally, the barrier lamp further includes a power supply unit, which is respectively connected to the wireless receiving unit, the second main control unit, and the driving unit, and is configured to respectively provide electric energy to the wireless receiving unit, the second main control unit, and the driving unit.

Optionally, the barrier lamp further includes a local lamp effect control unit, connected to the second main control unit, and configured to generate a local pulse signal and transmit the local pulse signal to the second main control unit; the second main control unit is used for storing the local pulse signal and sending the local pulse signal to the driving unit; the driving unit is used for amplifying the local pulse signal into a display signal and sending the display signal to the light-emitting component.

The embodiment of the utility model provides a technical proposal, which comprises a remote lamp effect control module and an obstruction light; wherein: the remote lamp effect control module comprises a remote lamp effect control unit, a first main control unit, a wireless transmitting unit and a trigger key; the barrier lamp comprises a wireless receiving unit, a second main control unit, a driving unit and a light-emitting assembly; the first main control unit is respectively connected with the remote lamp effect control unit, the trigger key and the wireless transmitting unit; the second main control unit is respectively connected with the wireless receiving unit and the driving unit, and the driving unit is connected with the light-emitting component; the wireless transmitting unit is connected with the wireless receiving unit; the remote lamp effect control unit generates a remote pulse signal and transmits the remote pulse signal to the first main control unit; the trigger key generates a trigger signal and sends the trigger signal to the first main control unit; the first main control unit transmits the remote pulse signal to the second main control unit through the wireless transmitting unit and the wireless receiving unit in sequence when receiving the trigger signal; the second main control unit stores the remote pulse signal and sends the remote pulse signal to the driving unit; the driving unit amplifies the remote pulse signal into a display signal and sends the display signal to the light-emitting component; the display signal comprises at least one of an energy signal, an intensity signal, a color signal, a flicker signal and a flicker period signal; the light emitting component generates a light source according to the display signal. Through carrying out the embodiment of the utility model provides a technical scheme can realize that offshore platform uses the barrier lamp of same kind of model, practices thrift the cost, reduces field operation's risk, carries out remote control and debugging to the barrier lamp high-efficiently in a flexible way.

Drawings

In order to clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the description below are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a barrier lamp control device according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of two eight-bit binary dial switches according to an embodiment of the present invention;

fig. 3 is a schematic layout view of a light-emitting LED lamp provided in an embodiment of the present invention;

fig. 4 is a schematic diagram of a display effect of a remote lamp effect control module according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

Fig. 1 is a schematic structural diagram of a barrier lamp control device according to an embodiment of the present invention. The present embodiment is applicable to the case of controlling the obstruction light, and the apparatus can be implemented by software and/or hardware, and can be integrated into the electronic device for controlling the obstruction light. As shown in fig. 1, the device comprises a remote lamp effect control module 1 and an obstruction light 2; wherein:

the remote lamp effect control module 1 comprises a remote lamp effect control unit 11, a first main control unit 12, a wireless transmitting unit 13 and a trigger key 14; the obstruction light 2 comprises a wireless receiving unit 21, a second main control unit 22, a driving unit 23 and a light-emitting assembly 24;

the first main control unit 12 is respectively connected with the remote lamp effect control unit 11, the trigger key 14 and the wireless transmitting unit 13; the second main control unit 22 is respectively connected with the wireless receiving unit 21 and the driving unit 23, and the driving unit 23 is connected with the light emitting assembly 24; the wireless transmitting unit 13 is connected with the wireless receiving unit 21;

the remote lamp effect control unit 11 generates a remote pulse signal and transmits the remote pulse signal to the first main control unit 12;

the trigger key 14 generates a trigger signal and sends the trigger signal to the first main control unit 12;

the first main control unit 12 transmits the remote pulse signal to the second main control unit 22 through the wireless transmitting unit 13 and the wireless receiving unit 21 in sequence when receiving the trigger signal;

the second main control unit 22 stores the remote pulse signal and transmits the remote pulse signal to the driving unit 23;

the driving unit 23 amplifies the remote pulse signal into a display signal and transmits the display signal to the light emitting assembly 24; the display signal comprises at least one of an energy signal, an intensity signal, a color signal, a flicker signal and a flicker period signal;

the light emitting assembly 24 generates a light source according to the display signal.

Illustratively, the remote light effect control module 1 may be a remote controller. The remote light effect control unit 11 may be a two eight bit binary dial switch. The first main control unit 12 may be a main board including a control circuit integrated in the remote controller. The wireless transmitting unit 13 may be a wireless module using wireless technology. The trigger button 14 may be a trigger button. The wireless receiving unit 21 may be a wireless module using wireless technology. The second main control unit 22 may be a main board including a control circuit integrated in the barrier lamp 2. The driving unit 23 may be a driving circuit. The light assembly 24 may be an LED lamp.

Fig. 2 is a schematic structural diagram of two eight-bit binary dial switches according to an embodiment of the present invention. As shown in fig. 2, in this scheme, the display parameters may be set by different dial switch combinations in the two eight-bit binary dial switches to generate corresponding remote pulse signals, and the remote pulse signals are transmitted to the first master control unit 12 for storage. Wherein, the display parameter may be an energy use parameter. The display parameter may be an intensity parameter. The display parameter may be a color parameter. The display parameter may be a blinking pulse parameter. The display parameter may be a blinking time parameter. The display parameters can be set according to actual needs. The number of bits of the dial switch in the dial switch combination may be one bit. The number of digits of the dial switch in the dial switch combination can also be two. The number of bits of the dial switch in the dial switch combination can also be eight. The number of bits of the dial switch in the dial switch combination can be set according to actual needs. The remote pulse signal may be an energy pulse signal. The remote pulse signal may also be an intensity pulse signal. The remote pulse signal may also be a color pulse signal. The remote pulse signal may also be a blinking pulse signal. The remote pulse signal may also be a blinking time pulse signal. The remote pulse signal can be set according to actual needs.

After the display parameters are set, the trigger button 14 generates a trigger signal if a trigger event is detected (e.g., the trigger button 14 is pressed), and sends the trigger signal to the first master control unit 12. After receiving the trigger signal, the first main control unit 12 sends the previously stored remote pulse signal to the wireless transmitting unit 13, the wireless transmitting unit 13 sends the remote pulse signal to the wireless receiving unit 21, the wireless receiving unit 21 sends the remote pulse signal to the second main control unit 22, and the second main control unit 22 stores the remote pulse signal and sends the remote pulse signal to the driving unit 23. Since the remote pulse signal is a low voltage signal, the driving unit 23 can amplify the remote pulse signal into a display signal capable of lighting the LED lamp, and the display signal is used to drive the light emitting assembly 24 to display a corresponding effect, for example, according to a certain energy utilization mode. Alternatively, a certain light color is displayed. Alternatively, the display is performed with a certain illumination intensity. Alternatively, the display is performed in regular blinking cycles. Alternatively, the display is performed with some irregular flashing cycle. The second master unit 22 may permanently store the current remote pulse signal until the next remote pulse signal is received.

At present, many obstacle lights in various shapes and specifications are available, such as aviation obstacle lights, navigation lights, warning lights and the like, but for fixed-type obstacle lights, the functions are single, when the fixed-type obstacle lights are used in different places or different countries, the choices of colors, light intensity and flashing frequency are not necessarily the same, an independent control box is needed to control the fixed-type obstacle lights, many types of obstacle lights are needed for realizing different functions, and the flexibility and the universality are poor.

The embodiment of the utility model provides a technical scheme, including remote lamp effect control module and obstacle lamp; wherein: the remote lamp effect control module comprises a remote lamp effect control unit, a first main control unit, a wireless transmitting unit and a trigger key; the barrier lamp comprises a wireless receiving unit, a second main control unit, a driving unit and a light-emitting assembly; the first main control unit is respectively connected with the remote lamp effect control unit, the trigger key and the wireless transmitting unit; the second main control unit is respectively connected with the wireless receiving unit and the driving unit, and the driving unit is connected with the light-emitting component; the wireless transmitting unit is connected with the wireless receiving unit; the remote lamp effect control unit generates a remote pulse signal and transmits the remote pulse signal to the first main control unit; the trigger key generates a trigger signal and sends the trigger signal to the first main control unit; the first main control unit transmits the remote pulse signal to the second main control unit through the wireless transmitting unit and the wireless receiving unit in sequence when receiving the trigger signal; the second main control unit stores the remote pulse signal and sends the remote pulse signal to the driving unit; the driving unit amplifies the remote pulse signal into a display signal and sends the display signal to the light-emitting component; the display signal comprises at least one of an energy signal, an intensity signal, a color signal, a flicker signal and a flicker period signal; the light emitting component carries out light source display according to the display signal. Through carrying out the embodiment of the utility model provides a technical scheme can realize using the barrier lamp of same kind of model at offshore platform, practices thrift the cost, reduces field operation's risk, carries out remote control and debugging to the barrier lamp high-efficiently in a flexible way.

In this embodiment, optionally, the remote light effect control unit 11 includes at least one dial switch combination; the dial switch combinations are arranged according to a preset function sequence; the dial switch combination comprises: the first dial switch combination is used for generating an energy pulse signal; the second dial switch combination is used for generating an intensity pulse signal; the third dial switch combination is used for generating a color pulse signal; the fourth dial switch combination is used for generating a flicker pulse signal; and the fifth dial switch combination is used for generating a flicker time pulse signal.

As shown in fig. 2, the value of the dial switch is 1 when the dial switch is in the ON position, and the value of the dial switch is 0 when the dial switch is in the OFF position. And a first dial switch combination (a) for defining the energy using mode of the barrier lamp 2 and generating an energy using pulse signal. Wherein the energy use mode may be an energy saving mode. The energy use mode may be a normally bright mode. The energy utilization mode can be set according to actual needs. And the second dial switch combination (b, c) is used for defining the intensity of the light emitted by the barrier lamp 2 and generating an intensity pulse signal. Wherein the intensity of the light may be low intensity. The intensity of the light may also be high. The intensity of the light may also be medium intensity. The intensity of the light may also be non-intensity, i.e. non-bright. The intensity of the light can be set according to actual needs. And the third dial switch combination (d, e) is used for defining the color of the light emitted by the barrier lamp 2 and generating a color pulse signal. Wherein the light color may be white. The light color may also be yellow. The light color may also be green. The light color may also be red. The light color can be set according to actual needs. And the fourth dial switch combination (f, g) is used for defining whether the on and off time of the barrier lamp 2 is the same or not and generating a flicker pulse signal. Wherein, the time of the light is the same as the time of the light, and the time of the light is the same as the time of the light. If the on time and the off time are different, irregular flicker is indicated. And a fifth dial switch combination (i, j, k, l, m, n, o, p) for defining the flashing time and the flashing rule of the barrier lamp 2 and generating a flashing time pulse signal. According to the scheme, under the condition of regular flashing, the flashing period, namely the flashing time, can be determined according to the positions of all the dial switches in the fifth dial switch combination (i, j, k, l, m, n, o, p). In the scheme, under the condition of irregular flicker, the flicker form can be determined according to the positions of all the dial switches in the fifth dial switch combination (i, j, k, l, m, n, o, p), for example, the flicker is performed according to Morse code.

In addition, the setting of the dial switch h is reserved and can be defined according to the requirements of users or other standards.

Therefore, the dial switch capable of generating different pulse signals is arranged, and the setting of a plurality of attributes of the barrier lamp can be simply and flexibly realized.

In this embodiment, optionally, the first toggle actuator assembly includes a first toggle actuator, and is specifically configured to: when the first dial switch is positioned at a first position, the energy utilization pulse signal is an energy-saving pulse signal; or when the first dial switch is located at the second position, the energy utilization pulse signal is a normally bright pulse signal.

Wherein the first position may be an ON position and the second position may be an OFF position. Alternatively, the first position may be an OFF position and the second position may be an ON position. The preferred first position of this scheme is the ON position, and the second position is the OFF position. When the first dial switch a is positioned at the first position, the energy pulse signal is used as an energy-saving pulse signal, and the barrier lamp 2 can be controlled to start working when detecting that nearby light is dark and stop working when the nearby light is bright according to the installed light-operated probe, so that the purpose of saving energy is achieved. When the first dial switch a is positioned at the second position, the energy pulse signal is used as a normally-on pulse signal, and the barrier lamp 2 can be controlled to be in a working state as long as electricity is supplied.

Therefore, the energy consumption mode of the barrier lamp can be simply and flexibly controlled by setting the dial switch combination for generating the energy consumption pulse signal, and energy can be saved.

In a possible embodiment, optionally, the second toggle actuator combination includes two second toggle actuators, specifically configured to: when all the second dial switches are located at the first position, the strength pulse signal is a high strength pulse signal; or when all the second dial switches are located at the second position, the strength pulse signal is a non-strength pulse signal; or when the first second dial switch is located at the first position and the second dial switch is located at the second position, the strength pulse signal is a medium strength pulse signal; or when the first second dial switch is located at the second position and the second dial switch is located at the first position, the strength pulse signal is a low-strength pulse signal.

When the second dial switches b and c are both located at the ON position, the intensity pulse signal is a high-intensity pulse signal, and the light emitted by the obstruction light 2 can be controlled to be high-intensity. When the second dial switches b and c are both located at the OFF position, the intensity pulse signal is a non-intensity pulse signal, and the barrier lamp 2 can be controlled not to be turned on. When the second dial switch b is located at the ON position and the second dial switch c is located at the OFF position, the intensity pulse signal is a medium intensity pulse signal, and the light emitted by the barrier lamp 2 can be controlled to be medium intensity. When the second dial switch b is located at the OFF position and the second dial switch c is located at the ON position, the intensity pulse signal is a low-intensity pulse signal, and the light emitted by the obstruction light 2 can be controlled to be low-intensity.

Because the mounting height of barrier lamp is different, and the light intensity and the scintillation frequency that use are also different, set up by the user, can widen application range. It should be noted that the setting of the illumination intensity by the user needs to meet the requirements of the relevant industry standards.

Therefore, the light intensity of the barrier lamp can be simply and flexibly controlled by setting the dial switch combination for generating the intensity pulse signal, and the application range and the use scene are widened.

In another possible embodiment, optionally, the third toggle actuator combination includes two third toggle actuators, specifically configured to: when all the third dial switches are located at the first position, the color pulse signals are red pulse signals; or when all the third dial switches are located at the second position, the color pulse signal is a white pulse signal; or when the first third dial switch is located at the first position and the second third dial switch is located at the second position, the color pulse signal is a green pulse signal; or when the first third dial switch is located at the second position and the second third dial switch is located at the first position, the color pulse signal is a yellow pulse signal.

When the third dial switches d and e are both located at the ON position, the color pulse signal is a red pulse signal, and the barrier lamp 2 can be controlled to emit red light. When the third dial switches d and e are both located at the OFF position, the color pulse signal is a white pulse signal, and the barrier lamp 2 can be controlled to emit white light. When the third dial switch d is located at the ON position and the third dial switch e is located at the OFF position, the color pulse signal is a green pulse signal, and the barrier lamp 2 can be controlled to emit green light. When the third dial switch d is located at the OFF position and the third dial switch e is located at the ON position, the color pulse signal is a yellow pulse signal, and the barrier lamp 2 can be controlled to emit yellow light.

Fig. 3 is a schematic layout view of a light-emitting LED lamp according to an embodiment of the present invention. As shown in fig. 3, the light-emitting LED lamps of four colors are arranged on the same plane, and the light of which color needs to be emitted, and the light-emitting LED lamps of which color can emit light, and the light-emitting LED lamps of different colors can be arranged in any shape according to the need. The number of the LED lamps is multiple of 4, and when the light intensity is low, the outermost circle of LED lamps emit light. When the light intensity is medium intensity, the LED lamps on the outermost circle and the secondary circle emit light simultaneously. When the light intensity is high, the LED lamps of the outermost ring, the secondary outer ring and the innermost ring emit light simultaneously. The function of adjusting color and light intensity is realized.

Therefore, by setting the dial switch combination for generating the color pulse signals, the display colors of the barrier lamps can be simply and flexibly controlled, and further the application under different scenes can be realized.

In yet another possible embodiment, optionally, the fourth toggle actuator combination includes two fourth toggle actuators, specifically configured to: when all the fourth dial switches are located at the first position, the flicker pulse signals are irregular flicker pulse signals; or when all the fourth dial switches are located at the second position, the flicker pulse signals are regular flicker pulse signals; or when one fourth dial switch is located at the first position and the other fourth dial switch is located at the second position, the flicker pulse signal is a normally bright pulse signal.

For example, when the fourth dial switches f and g are both located at the ON position, the blinking pulse signal is an irregular blinking pulse signal, that is, the ON and off times are different, and the barrier lamp 2 may be controlled to blink according to the morse code. When the fourth dial switches f and g are located at the OFF positions, the flicker pulse signals are regular flicker pulse signals, the on and OFF time is the same, and the barrier lamp 2 can be controlled to flicker regularly. When the fourth dial switch f is located at the ON position and the fourth dial switch g is located at the OFF position, or the fourth dial switch f is located at the OFF position and the fourth dial switch g is located at the ON position, the flicker pulse signal is a normally-ON pulse signal, and the barrier lamp 2 can be controlled to be normally ON.

The morse code is also called morse code, and is a signal code that is switched on and off, and different english letters, numbers and punctuation marks are expressed by different arrangement sequences.

Therefore, by setting the dial switch combination for generating the flicker pulse signal, the flicker pattern of the barrier lamp can be simply and flexibly controlled, and further the application under different scenes can be realized.

In this embodiment, optionally, the fifth dip switch combination includes 8 fifth dip switches, and the fifth dip switches are configured to determine a flashing period and perform flashing timing when all the fourth dip switches are located at the second position; or the fifth dial switch is used for carrying out flicker timing according to a Morse code meter when all the fourth dial switches are positioned at the first position.

Illustratively, when the fourth switches f and g are both in the OFF position, the fifth switches i to p are 0 when in the OFF position, and are defined as the following values when in the ON position:

i is 2 ⁰ ×10 ^-1 =0.1,j being 2 ¹ ×10 ^-1 K is 2 =0.2, ² ×10 ^-1 0.4,l is 2 ³ ×10 ^-1 =0.8,m is 2 ⁰ 1,n is 2 ¹ =2,o is 2 ² (ii) =4,p is 2 ³ And =8, the flicker period is an accumulated value of i to p.

For example, if the fifth dip switches i and k are in the ON position and the other fifth dip switches are in the OFF position, the blinking period is 0.1+0.4=0.5 seconds. When the fifth dial switch i, j, m, n, o is located at the ON position and the other fifth dial switches are located at the OFF position, the flashing period is 0.1+0.2+1+2+4=7.3s, and so ON. When all the fifth dial switches are located at the ON position, the flashing period is longest, i.e. 0.1+0.2+0.4+0.8+1+2+4+8=16.5 seconds.

When the fourth dial switches f and g are located at ON positions, the fifth dial switches i-p form an eight-bit binary code, the highest two bits are reserved bits, practical significance is avoided temporarily, influence is avoided when the fifth dial switches are located at any positions, and development is carried out subsequently according to user requirements. The fifth dial switches i to p represent morse codes from 0000 0000 to 0010 1111, and the fifth dial switches i to p from 0011 0000 to 1111 may be defined as other functions according to actual needs of users. The fifth dial switches i-p flash from 0000 0000 to 0010 1111 according to Morse code table corresponding to eight-bit binary code shown in Table 1:

TABLE 1

For example, when the o bit and the p bit in eight binary codes of the fifth dial switches i to p are both located at the ON position, the corresponding flashing character is 3, the barrier lamp 2 flashes in three short and two long periods, and the cycle is repeated; for example, when a character U is to be blinked, k bits, n bits, and p bits of the eight binary codes i to p are turned to the ON position, and the obstruction light 2 blinks in a cycle of two short bits and one long bit.

From this, through setting up the fifth dial switch, can realize cooperating with the fourth dial switch, can realize controlling the scintillation cycle and the scintillation rule of barrier lamp simply in a flexible way, and then can realize using under the different scenes.

In this embodiment, optionally, the remote light effect control module 1 further includes a display unit connected to the first main control unit 12; the first main control unit 12 is further configured to send the remote pulse signal to the display unit; and the display unit is used for displaying a setting result to a user when the remote pulse signal is received.

For example, fig. 4 is a schematic diagram of a display effect of the remote lamp effect control module 1 provided in the embodiment of the present invention. As shown in fig. 4, when the first dial switch a is located at the ON position, the second dial switch b is located at the ON position, the second dial switch c is located at the OFF position, the third dial switches d and e are both located at the ON position, the fourth dial switches f and g are both located at the OFF position, the fifth dial switch m is located at the ON position, and the other fifth dial switches are both located at the OFF position, the remote pulse signal is an energy-saving pulse signal, a medium-intensity pulse signal, a red pulse signal, a regular flashing pulse signal, and a flashing period is a 1s pulse signal. When the display unit receives the remote pulse signal sent by the first main control unit 12, the display content of the display unit is the content corresponding to the remote pulse signal.

Therefore, the setting result can be visually displayed to the user by setting the display unit, the problem that the user manually searches for the operation manual is avoided, and the use experience of the user can be improved.

In yet another possible embodiment, optionally, the barrier lamp 2 further includes a power supply unit respectively connected to the wireless receiving unit 21, the second main control unit 22, and the driving unit 23, for respectively supplying power to the wireless receiving unit 21, the second main control unit 22, and the driving unit 23.

Therefore, the power supply unit is arranged in the barrier lamp, so that power supply can be provided for all parts in the barrier lamp, and the barrier lamp can be ensured to work and operate stably.

In this embodiment, optionally, the barrier lamp 2 further includes a local lamp effect control unit, connected to the second main control unit 22, and configured to generate a local pulse signal and transmit the local pulse signal to the second main control unit 22; the second main control unit 22 is configured to store the local pulse signal and send the local pulse signal to the driving unit 23; and a driving unit 23 for amplifying the local pulse signal into a display signal and transmitting the display signal to the light emitting assembly 24.

Wherein, the local light effect control unit can be two eight-bit binary dial switches. According to the scheme, the display parameters can be respectively set through different dial switch combinations in the two eight-bit binary dial switches to generate corresponding local pulse signals, and the local pulse signals are transmitted to the second main control unit 22 to be stored and are simultaneously transmitted to the driving unit 23. Wherein, the display parameter may be an energy use parameter. The display parameter may be an intensity parameter. The display parameter may be a color parameter. The display parameter may be a blinking pulse parameter. The display parameter may be a blinking time parameter. The display parameters can be set according to actual needs. The number of bits of the dial switch in the dial switch combination may be one bit. The number of digits of the dial switch in the dial switch combination can also be two. The number of bits of the dial switch in the dial switch combination can also be eight. The number of bits of the dial switch in the dial switch combination can be set according to actual needs. The local pulse signal may be an energy pulse signal. The local pulse signal may also be an intensity pulse signal. The local pulse signal may also be a color pulse signal. The local pulse signal may also be a blinking pulse signal. The local pulse signal may also be a blinking time pulse signal. The local pulse signal can be set according to actual needs. Since the local pulse signal is a low voltage signal, the driving unit 23 can amplify the local pulse signal into a display signal that can turn on the LED lamp, and the display signal is used to drive the light emitting assembly 24 to display a corresponding effect, for example, according to a certain energy usage mode. Alternatively, a certain light color is displayed. Alternatively, the display is performed with a certain illumination intensity. Alternatively, the display is performed in regular blinking cycles. Alternatively, the display is performed with some irregular flashing cycle. The second master control unit 22 may permanently store the current local pulse signal until the next remote pulse signal or local pulse signal is received.

Therefore, the display parameters of the barrier lamps can be simply and flexibly controlled by arranging the local lamp effect control unit in the barrier lamps, and the barrier lamps can be suitable for more scenes.

It should be noted that the foregoing is only a preferred embodiment of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious modifications, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail with reference to the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the scope of the present invention.

Claims (10)

1. The barrier lamp control device is characterized by comprising a remote lamp effect control module and a barrier lamp; wherein:

the remote lamp effect control module comprises a remote lamp effect control unit, a first main control unit, a wireless transmitting unit and a trigger key; the barrier lamp comprises a wireless receiving unit, a second main control unit, a driving unit and a light-emitting assembly;

the first main control unit is respectively connected with the remote lamp effect control unit, the trigger key and the wireless transmitting unit; the second main control unit is respectively connected with the wireless receiving unit and the driving unit, and the driving unit is connected with the light-emitting assembly; the wireless transmitting unit is connected with the wireless receiving unit;

the remote lamp effect control unit generates a remote pulse signal and transmits the remote pulse signal to the first main control unit;

the trigger key generates a trigger signal and sends the trigger signal to the first main control unit;

the first main control unit transmits the remote pulse signal to the second main control unit through the wireless transmitting unit and the wireless receiving unit in sequence when receiving the trigger signal;

the second main control unit stores the remote pulse signal and sends the remote pulse signal to the driving unit;

the driving unit amplifies the remote pulse signal into a display signal and sends the display signal to the light-emitting component; the display signal comprises at least one of an energy signal, an intensity signal, a color signal, a flicker signal and a flicker period signal;

the light-emitting component generates a light source according to the display signal.

2. The apparatus of claim 1, wherein the remote light effect control unit comprises at least one dip switch combination; the dial switch combinations are arranged according to a preset function sequence; the dial switch combination comprises:

the first dial switch combination is used for generating an energy pulse signal;

the second dial switch combination is used for generating an intensity pulse signal;

the third dial switch combination is used for generating a color pulse signal;

the fourth dial switch combination is used for generating a flicker pulse signal;

and the fifth dial switch combination is used for generating a flicker time pulse signal.

3. The apparatus of claim 2, wherein the first toggle actuator assembly comprises a first toggle actuator configured to:

when the first dial switch is positioned at a first position, the energy utilization pulse signal is an energy-saving pulse signal; alternatively, the first and second liquid crystal display panels may be,

when the first dial switch is located at the second position, the energy utilization pulse signal is a normally bright pulse signal.

4. The apparatus of claim 3, wherein the second toggle actuator combination comprises two second toggle actuators, and is specifically configured to:

when all the second dial switches are located at the first position, the strength pulse signal is a high strength pulse signal; alternatively, the first and second electrodes may be,

when all the second dial switches are located at the second position, the strength pulse signal is a non-strength pulse signal; alternatively, the first and second liquid crystal display panels may be,

when the first second dial switch is located at the first position and the second dial switch is located at the second position, the strength pulse signal is a medium strength pulse signal; alternatively, the first and second electrodes may be,

and when the first second dial switch is positioned at the second position and the second dial switch is positioned at the first position, the strength pulse signal is a low-strength pulse signal.

5. The apparatus of claim 3, wherein the third toggle actuator combination comprises two third toggle actuators, and is specifically configured to:

when all the third dial switches are positioned at the first position, the color pulse signal is a red pulse signal; alternatively, the first and second electrodes may be,

when all the third dial switches are located at the second position, the color pulse signals are white pulse signals; alternatively, the first and second electrodes may be,

when the first third dial switch is positioned at the first position and the second third dial switch is positioned at the second position, the color pulse signal is a green pulse signal; alternatively, the first and second liquid crystal display panels may be,

and when the second third dial switch is positioned at the first position, the color pulse signal is a yellow pulse signal.

6. The apparatus of claim 3, wherein the fourth toggle actuator combination comprises two fourth toggle actuators, and is specifically configured to:

when all the fourth dial switches are located at the first position, the flicker pulse signals are irregular flicker pulse signals; alternatively, the first and second liquid crystal display panels may be,

when all the fourth dial switches are positioned at the second position, the flicker pulse signals are regular flicker pulse signals; alternatively, the first and second electrodes may be,

when one fourth dial switch is located at the first position and the other fourth dial switch is located at the second position, the flicker pulse signal is a normally bright pulse signal.

7. The apparatus of claim 3, wherein the fifth toggle combination includes 8 fifth toggle switches,

the fifth dial switch is used for determining a flicker period and carrying out flicker timing when all the fourth dial switches are positioned at the second position; alternatively, the first and second electrodes may be,

and the fifth dial switch is used for carrying out flashing timing according to the Morse code meter when all the fourth dial switches are positioned at the first position.

8. The device of claim 1, wherein the remote light effect control module further comprises a display unit connected to the first master control unit;

the first main control unit is also used for sending the remote pulse signal to the display unit;

and the display unit is used for displaying a setting result to a user when the remote pulse signal is received.

9. The device of claim 1, wherein the obstruction light further comprises a power supply unit respectively connected to the wireless receiving unit, the second main control unit, and the driving unit for respectively supplying power to the wireless receiving unit, the second main control unit, and the driving unit.

10. The apparatus of claim 1, wherein the obstruction light further comprises a local light effect control unit connected to the second master control unit for generating a local pulse signal and transmitting the local pulse signal to the second master control unit;

the second main control unit is used for storing the local pulse signal and sending the local pulse signal to the driving unit;

the driving unit is used for amplifying the local pulse signal into a display signal and sending the display signal to the light-emitting component.

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