阅读说明：本技术 用于室内栽培应用的照明系统的电源和通信适配器 (Power and communication adapter for lighting systems for indoor cultivation applications ) 是由 D.蔡 M.R.梅森 于 2020-05-08 设计创作，主要内容包括：提供了一种用于温室和室内栽培的自动控制器的适配器。该适配器包括电源输入端、电源输出端、控制输入端、主控制器和第一控制输出端。电源输出端与电源输入端电耦合。控制输入端配置为从自动化温室控制器接收原始控制信号。主控制器与电源输入端耦合,以便于从电源向主控制器供电。主控制器与控制输入端进行信号通信,并配置为将来自自动化温室控制器的原始控制信号转换成LED兼容驱动信号。第一控制输出端与主控制器进行信号通信。所述原始控制信号符合第一信号协议,而所述LED兼容驱动信号符合与第一信号协议不同的第二信号协议。(An adapter for an automatic controller for greenhouses and indoor cultivation is provided. The adapter comprises a power input end, a power output end, a control input end, a main controller and a first control output end. The power supply output end is electrically coupled with the power supply input end. The control input is configured to receive a raw control signal from an automated greenhouse controller. The master controller is coupled to the power input to facilitate supplying power from the power source to the master controller. The main controller is in signal communication with the control input and is configured to convert a raw control signal from the automated greenhouse controller into an LED compatible drive signal. The first control output is in signal communication with the master controller. The raw control signal conforms to a first signal protocol and the LED-compatible drive signal conforms to a second signal protocol different from the first signal protocol.)

1. An adapter for automated controllers for greenhouses and indoor cultivation, the adapter comprising:

A power input configured to receive power from a power source;

a power output electrically coupled to the power input and configured to transmit the received power to a Light Emitting Diode (LED) light module;

a control input configured to receive a raw control signal from an automated greenhouse controller;

a main controller coupled with the power supply input to facilitate power supply thereto from a power supply, the main controller in signal communication with the control input and configured to convert a raw control signal from the automated greenhouse controller into an LED compatible drive signal; and

a first control output in signal communication with the master controller and configured to facilitate sending an LED compatible drive signal to the LED lamp,

wherein the original control signal conforms to a first signal protocol and the LED compatible drive signal conforms to a second signal protocol different from the first signal protocol.

2. The adapter of claim 1, further comprising a second control output in signal communication with the control input and configured to send the raw control signal to another adapter.

3. The adapter of claim 2, further comprising an amplifier module in signal communication with each of the control input and the second control output and configured to facilitate amplification of the original control signal.

4. The adapter of claim 3, wherein the amplifier module is in signal communication with a host controller.

5. The adapter of claim 1, further comprising a transformer module electrically coupled to the power input and the host controller, wherein:

the power from the power source has a first voltage;

the transformer module is configured to convert a first voltage of the power to a second voltage for powering the master controller; and is

The second voltage is less than the first voltage.

6. The adapter of claim 5, wherein the transformer module includes a flyback circuit.

7. The adapter of claim 1, wherein the host controller further comprises a security module configured to detect a fault condition of the adapter and facilitate shutting down the adapter in response to the fault condition.

8. The adapter of claim 1, further comprising a kill switch electrically coupled to the power input and the power output and in signal communication with the host controller, wherein the host controller is configured to selectively actuate the kill switch to interrupt power to the power output.

9. The adapter of claim 1, wherein the master controller further comprises a feedback circuit to facilitate correction of the LED compatible drive signal.

10. The adapter of claim 1, further comprising:

an input power interface associated with a power input;

an input control interface associated with the control input; and

an output power/control interface associated with the power output and the first control output.

11. A lighting system for an indoor cultivation facility, the lighting system comprising:

an adapter, comprising:

a power input configured to receive power from a power source;

a power supply output terminal electrically coupled to the power supply input terminal;

a control input configured to receive a raw control signal from an automated greenhouse controller;

a main controller coupled with the power supply input to facilitate power supply thereto from a power supply, the main controller in signal communication with the control input and configured to convert a raw control signal from the automated greenhouse controller into an LED compatible drive signal; and

a first control output in signal communication with the master controller; and

an LED light fixture, comprising:

an LED drive circuit in signal communication with the first control output and electrically coupled to the power supply output; and

a plurality of LED lamps electrically coupled to the LED driver circuit, wherein:

The main controller sends an LED compatible driving signal to the LED lamp so as to control the plurality of LED lamps; and is

The raw control signal conforms to a first signal protocol and the LED-compatible drive signal conforms to a second signal protocol different from the first signal protocol.

12. The lighting system of claim 11, wherein the adapter comprises a second control output in signal communication with the control input and configured to send the raw control signal to another adapter.

13. The lighting system of claim 12, wherein the adapter further comprises an amplifier module in signal communication with each of the control input and the second control output and configured to facilitate amplification of the original control signal.

14. The lighting system of claim 13, wherein the amplifier module is in signal communication with a master controller.

15. The lighting system of claim 11, wherein the adapter further comprises a transformer module electrically coupled to the power input and the host controller, wherein:

the power from the power source has a first voltage;

the transformer module is configured to convert a first voltage of the power to a second voltage for powering the master controller; and is

The second voltage is less than the first voltage.

16. The lighting system of claim 11, wherein the master controller further comprises a safety module configured to detect a fault condition of the adapter and facilitate shutting down the adapter in response to the fault condition.

17. The lighting system of claim 11, wherein the adapter further comprises a kill switch electrically coupled to the power input and the power output and in signal communication with the master controller,

wherein the main controller is configured to selectively drive the cut-off switch so as to interrupt power supply to the power supply output terminal and the LED lamp.

18. The lighting system of claim 11, wherein the master controller further comprises a feedback circuit to facilitate correction of the LED compatible drive signal.

19. An adapter for automated controllers for greenhouses and indoor cultivation, the adapter comprising:

a power input configured to receive power from a power source;

a power supply output electrically coupled to the power supply input and configured to transmit the received power to the LED lamp module;

a control input configured to receive a raw control signal from an automated greenhouse controller;

a main controller coupled with the power supply input to facilitate power supply thereto from a power supply, the main controller in signal communication with the control input and configured to convert a raw control signal from the automated greenhouse controller into an LED compatible drive signal;

A first control output terminal in signal communication with the master controller and configured to facilitate sending of the LED compatible drive signal to the LED lamp; and

a second control output in signal communication with the control input and configured to send the original control signal to another adapter;

an amplifier module in signal communication with each of the control input and the second control output and configured to facilitate amplification of an original control signal; and

a disconnect switch electrically coupled to the power input and the power output and in signal communication with a master controller, wherein the master controller is configured to selectively actuate the disconnect switch to electrically disconnect the power input from the power output, wherein:

the master controller further includes a feedback circuit to facilitate correction of the LED compatible drive signal;

the host controller further includes a security module configured to detect a fault condition of the adapter and facilitate shutting down the adapter in response to the fault condition; and is

The raw control signal conforms to a first signal protocol and the LED-compatible drive signal conforms to a second signal protocol different from the first signal protocol.

20. The adapter of claim 19, further comprising a transformer module electrically coupled to the power input and the host controller, wherein:

The power from the power source has a first voltage;

the transformer module is configured to convert a first voltage of the power to a second voltage for powering the master controller; and is

The second voltage is less than the first voltage.

Technical Field

The devices described below relate generally to powering and controlling lighting systems. Specifically, an adapter is provided that receives raw control signals from greenhouse and indoor cultivation automation systems, translates the raw control signals into Light Emitting Diode (LED) compatible control signals, and transmits the LED compatible control signals to facilitate control of LED luminaires.

Background

Conventional greenhouse and indoor cultivation automation systems include an automated greenhouse controller that sends control signals to gas discharge (HID) and/or xenon lamps to control dimming, scheduling, and other parameters of the HID and/or xenon lamps. Control signals sent from an automated greenhouse controller for controlling these types of lamps are generally not backward compatible with LED lamps. Thus, upgrading a greenhouse or other indoor cultivation facility with LED lights typically requires a complete replacement of the entire greenhouse automation system with an LED compatible system, which can be time consuming and expensive.

Drawings

Various embodiments will become better understood with regard to the following description, appended claims, and accompanying drawings where:

FIG. 1 is a schematic diagram depicting a lighting system having an adapter and an LED light fixture, according to one embodiment;

FIG. 2 is a front isometric view of the adapter of FIG. 1 according to one embodiment;

FIG. 3 is a rear isometric view of the adapter of FIG. 2;

FIG. 4 is a front isometric view of the LED light fixture of FIG. 1; and

fig. 5 is a schematic view of the adapter of fig. 1.

Detailed Description

The embodiments are described in detail below with reference to the drawings and examples of fig. 1-5, wherein like reference numerals designate identical or corresponding elements throughout the several views. A lighting system 10 for an indoor cultivation facility (e.g., a greenhouse) is generally shown in fig. 1 and is shown to include an automated greenhouse controller 11, an adapter 12 coupled with the automated greenhouse controller 11, and an LED light fixture 14 coupled with the adapter 12. The automated greenhouse controller 11 is configured to send raw control signals that are compatible with and configured to control HID lamps, xenon lamps, or various non-LED type lighting devices. As explained in further detail below, the adapter 12 may be configured to receive raw control signals from the automated greenhouse controller 11, translate the raw control signals into LED-compatible control signals, and communicate the LED-compatible control signals to the LED luminaire 14 in order to control dimming, scheduling, or other control parameters of the LED luminaire 14.

Referring now to fig. 1, adapter 12 may be in signal communication (e.g., communicatively coupled) with other adapters (shown in phantom) similar to adapter 12. In this way, raw control signals may be communicated from adapter 12 to other adapters and translated by other LED fixtures (shown in phantom) into LED compatible signals to control each LED fixture substantially simultaneously. Thus, when retrofitting a lighting system with LED light fixtures (e.g., 14), one or more adapters (e.g., 12) may be used in conventional lighting systems without requiring replacement of the automated greenhouse controller 11, which replacement may be expensive and time consuming.

Referring now to fig. 2 and 3, the adapter 12 may be understood as a representative example of each of the other adapters shown in fig. 1. The adapter 12 may include an input power interface 16 (fig. 2) and an output power/control interface 18 (fig. 3). A power source 19 (fig. 1), such as an external ac power source (e.g., a wall outlet), may be electrically coupled to the input power interface 16 via a power cord 20 attached to the input power interface 16 so that external power may be provided to the adapter 12. The output power/control interface 18 may be electrically coupled with the LED light fixture 14 via a power/communication cable 22 that facilitates power delivery from a power source 19 (fig. 1) to power the LED light fixture 14. In one embodiment, the adapter 12 and the LED lamp 14 may be configured to operate at an input power between about 85 volts ac and about 347 volts ac (e.g., 750 watts load capacity).

The adapter 12 may also include an input control interface 24 (FIG. 2) and an output control interface 26 (FIG. 3). The automated greenhouse controller 11 may be communicatively coupled with the input control interface 24 by a communication cable 28 attached to the input control interface 24 to facilitate the transfer of raw control signals from the automated greenhouse controller 11 to the adapter 12. Output control interface 26 may be communicatively coupled (e.g., in signal communication) with another adapter (as shown in phantom in fig. 1) or another communication device via a communication cable 30 so that raw control signals may be communicated to one or more downstream adapters/communication devices. In one embodiment, each of the input power interface 16, the output power/control interface 18, the input control interface 24, and the output control interface 26 may include a Wieland type connector. However, it should be appreciated that any other suitable alternative interface is contemplated for input power interface 16, output power/control interface 18, input control interface 24, and/or output control interface 26, such as a releasable male or female interface of a different connection type (e.g., a standard jack (RJ) interface) or a hardwired connection. It should also be understood that the cable 20, the power/communication cable 22, the communication cable 28, and the communication cable 30 may each have opposing connections compatible with the interface to which they are connected.

As shown in fig. 4, the LED light fixture 14 may include an input power/control interface 32 and a plurality of LED lights 34. The input power/control interface 32 may be coupled to the output power/control interface 18 of the adapter 12 via a power/communication cable 22. In one embodiment, the input power/control interface 32 may be a Wieland type connector, although other types of connectors are contemplated. As described in further detail below, power from input power interface 16 and LED compatible drive signals generated by adapter 12 may be carried/communicated to LED light fixture 14 via power/communication cable 22 to facilitate powering and controlling LED lights 34 in accordance with raw control signals from automated greenhouse controller 11.

Referring now to FIG. 5, there is shown a schematic view of the adapter 12 and LED lamp 14, which will now be described. The adapter 12 may include a communication system 40 (shown in phantom) and a power system 42 (shown in solid). Communication system 40 may include an amplifier module 44, a master controller 46, an analog-to-digital converter (ADC)48, and a digital-to-analog converter (DAC) 50. The amplifier module 44 may be in signal communication with an ADC 48. The master controller 46 may be in signal communication with an ADC 48 and a DAC 50.

Input control interface 24 may include a control input 52 and output control interface 26 may include a control output 54. Each of the control input 52 and the control output 54 may be in signal communication with the amplifier module 44 such that the control input 52 and the control output 54 are in signal communication with each other via the amplifier module 44 to facilitate sending the original control signal from the control input 52 to the control output 54. Control input 52 may be in signal communication with automated greenhouse controller 11 via communication cable 28 to receive raw control signals from automated greenhouse controller 11. The control output 54 may be in signal communication with a downstream adapter via the communication cable 30 to facilitate sending raw control signals from the amplifier module 44 to the downstream adapter.

Referring again to fig. 5, the output power/control interface 18 may include a control output 56 in signal communication with the master controller 46 (via DAC 50). The LED light fixture 14 may include an LED drive circuit 58 electrically coupled to the LED lamp 34 and configured to control operation (e.g., dimming/intensity) of the LED lamp 34. The LED driver circuit 58 may be in signal communication with the control output 56 via the power/communication cable 22.

When the raw control signal from the automated greenhouse controller 11 is sent to the control input 52, the amplifier module 44 may amplify the raw control signal to compensate for any degradation of the raw control signal (e.g., due to transmission losses along the communication cable 28). The amplified control signal may be communicated to the control output 54 and to a downstream adapter/communication device. Each downstream adapter may amplify the raw control signal in a similar manner to maintain its integrity as it travels along the adapter network (e.g., as shown by the dashed lines in fig. 1). In one embodiment, the amplifier module 44 may include a plurality of mode chokes and amplifier circuits (e.g., operational amplifiers) configured to facilitate amplification of the original control signal.

The amplifier module 44 may also route the amplified raw control signal to the main controller 46 through the ADC 48. The master controller 46 may then convert the amplified control signal into an LED compatible drive signal, which is then routed via DAC50 to a control output 56 to be sent to an LED drive circuit 58 of the LED light fixture 14 for controlling the LED light 34, as described below. In one embodiment, each of the ADC 48 and DAC50 may include amplifier type circuits that facilitate analog-to-digital conversion and digital-to-analog conversion, respectively, of the signal. However, it should be understood that any of a variety of analog-to-digital converters and digital-to-analog converters are contemplated.

The raw control signal sent from the automated greenhouse controller 11 may not be compatible with the LED driver circuit 58 and therefore cannot directly control the intensity of the light emitted from the LED light fixture 14. Accordingly, the main controller 46 may be configured to convert (e.g., translate) the raw control signals sent from the automated greenhouse controller 11 into LED compatible drive signals capable of driving the LED drive circuits 58 to control the intensity of the light emitted by the LED light fixtures 14. The relationship between the raw control signal sent by the automated greenhouse controller 11 and the LED compatible drive signal sent to the LED drive circuit 58 may be a function of the respective signal protocol used by each of the automated greenhouse controller 11 and the LED drive circuit 58. For example, the automated greenhouse controller 11 may conform to the HID/xenon lamp protocol which generates a 1-10 volt DC control signal for varying the dimming of the associated HID/xenon lamp between 0% intensity and 100% intensity. However, the LED driver circuit 58 may conform to another protocol for dimming the LED lamp 34 between 10% intensity and 100% intensity based on an LED compatible drive signal between approximately 1-8 volts dc. In such an example, the main controller 46 may be configured to generate a 1-8 volt direct current LED compatible drive signal based on the dimming intensity requested by the raw control signal from the automated greenhouse controller 11.

It should be appreciated that the master controller 46 may receive or generate signals conforming to any of a variety of suitable alternative signal protocols, such as BACnet, ModBus, or RS 485. The main controller 46 may be programmed with predefined parameters (e.g., in firmware) that control the conversion of the original control signal to the LED compatible drive signal. In one embodiment, the main controller 46 may be preprogrammed with protocol specific parameters unique to the automated greenhouse controller 11 and the LED driver circuit 58. In another embodiment, the main controller 46 may be configured to detect a signal protocol of each of the automated greenhouse controller 11 and the LED driver circuit 58 and generate an LED compatible drive signal accordingly.

The master controller 46 is shown to include a control module 60 and a security module 62. Control module 60 may be configured to facilitate conversion of raw control signals from automated greenhouse controller 11 into LED compatible drive signals. The safety module 62 may be configured to detect a fault condition of the adapter 12 (e.g., a leakage alternating current in the LED light fixture 14) and shut down the adapter 12 in response to the fault condition. In one embodiment, each of the control module 60 and the security module 62 may include an integrated circuit, such as a microcontroller unit.

Master controller 46 may also include a feedback circuit 64 that extends to the output of DAC 50 and is capable of automatically correcting the LED compatible drive signal. The master controller 46 may monitor the LED-compatible drive signal via the feedback circuit 64 and may adjust the dc voltage of the LED-compatible drive signal to ensure that proper dimming accuracy is maintained (e.g., to compensate for any voltage loss across the DAC 50 and/or other voltage losses).

With continued reference to FIG. 5, the input power interface 16 may include a power input 66, and the output power/control interface 18 may include a power output 68 electrically coupled to the power input 66 via a main bus 70. The power supply output 68 may be electrically coupled to the LED driver circuit 58 via the power/communication cable 22. The power input 66 may receive power (e.g., via the power cord 20) from a power source 19 (fig. 1) coupled to the input power interface 16. Power may be routed along the main bus 70 and thereby delivered to the power output 68 and the LED light fixture 14 to power the LED light fixture 14. The control output 56 and the power output 68 may be housed within the output power/control interface 18 so that power and control signals from the adapter 12 may be transmitted to the LED lamp 14 on the same cable (e.g., the power/communication cable 22).

In another embodiment, the adapter 12 and the LED light fixture 14 may include separate interfaces for the control output 56 and the power output 68, respectively, so that the power and LED compatible drive signals are transmitted to the LED light fixture 14 along different cables.

Power system 42 may include a transformer module 72 configured to convert power (e.g., ac power) from main bus 70 to power (e.g., dc power) for powering communication system 40. In one embodiment, the transformer module 72 may include a flyback circuit.

Transformer module 72 may be configured to generate different dc voltages (e.g., 5 vdc, 12 vdc, 15 vdc) for communication system 40. In one embodiment, the transformer module 72 may include a plurality of driver circuits 44a, 46a, 48a, 50a, each of which generates a dc voltage for powering each of the amplifier module 44, the main controller 46, the ADC 48 and the DAC 50, respectively. For example, driver circuit 44a may generate 15 volts DC for amplifier module 44, driver circuit 46a may generate 5 volts DC for main controller 46, and driver circuits 48a, 50a may generate 12 volts DC for ADC 48 and DAC 50, respectively.

The power system 42 may also include a cut-off switch 74 electrically coupled to each of the power inputs 66 and power outputs 68, and configured to selectively disconnect the power inputs 66 from the power outputs 68 to interrupt power to the LED light fixture 14, thereby turning off the LED light fixture 14. The kill switch 74 may be coupled to the master controller 46, and the master controller 46 may selectively operate the kill switch 74 in response to the raw control signals. For example, in some cases, the LED drive circuit 58 may not be able to dim the LED lamp 34 to 0% intensity (e.g., turn off the LED lamp 34) when called upon by the original control signal from the automated greenhouse controller 11. At this point, when the raw control signal from the automated greenhouse controller 11 requires 0% intensity, the main controller 46 may be configured to operate the cut-off switch 74 to turn off the LED lamp 34. The host controller 46 may also selectively operate the kill switch 74 to kill the adapter 12 in response to the security module 62 detecting an adapter failure condition.

The power system 42 may also include an LED indicator light 76 powered by the driver circuit 76a (e.g., at 5 volts dc). When the adapter 12 is on, the main controller 46 may selectively illuminate the LED indicator lights 76 to provide a visual indication to the user.

As described above, the adapter 12 may be installed in the lighting system 10 when retrofitting the lighting system 10 with the LED light fixture 14, as shown in fig. 1. One example of the operation of the adapter 12 in the lighting system 10 will now be discussed. In this example, the automated greenhouse controller 11 may be configured to generate a 1-10 volt dc control signal (e.g., for an HID/xenon lamp), where the 1 volt dc control signal is associated with 0% intensity (e.g., off) and the 10 volt dc control signal is associated with 100% intensity (e.g., fully on). However, the LED driver circuit 58 may be configured to receive an LED compatible drive signal between 1-8 volts DC, where a 1 volt DC LED compatible drive signal is associated with 10% intensity and an 8 volt DC LED compatible drive signal is associated with 100% intensity (e.g., fully on).

When automated greenhouse controller 11 sends a control signal to adapter 12 that requires dimming LED light fixture 14 to between about 10% intensity and about 100% intensity (e.g., the original control signal is between 1.9 vdc and 10 vdc), master controller 46 may generate an appropriate LED-compatible drive signal between 1 vdc and 8 vdc to control dimming of the LED light fixture accordingly. During the sending of the LED compatible drive signal to the LED drive circuit 58, the master controller 46 may sense the voltage of the LED compatible drive signal through the feedback circuit 64 and ensure that the voltage of the LED compatible drive signal sent from the DAC 50 is properly correlated with the dimming required by the original control signal. When the automated greenhouse controller 11 sends a control signal to the adapter 12 that requires the LED lamp 14 to be fully dimmed to 0% intensity (e.g., the original control signal is between 0-1 vdc), the master controller 46 may recognize that the LED drive circuit 58 cannot dim the LED lamp 34 to 10% intensity (due to the configuration of the LED drive circuit 58 and the LED lamp 34), and instead operate the shutdown switch 74 to interrupt the ac power to the LED lamp 14 to shut down the LED lamp 34. Throughout the operation of the adapter 12, the safety module 62 may monitor the control module 60 for a fault condition. If a fault condition exists (e.g., current leakage at the LED lamp 14 damages the control module 60), the safety module 62 may facilitate operation of the cut-off switch 74 to interrupt AC power to the LED lamp 14, thereby turning off the LED lamp 34 and preventing further damage to the adapter 12.

The foregoing description of embodiments and examples is exemplary and explanatory only. The description is not intended to be exhaustive or to limit the forms disclosed. Various modifications are possible in light of the above teachings. Some of these modifications have been discussed herein, others will be readily apparent to those skilled in the art. The embodiments were chosen and described in order to illustrate various embodiments. Of course, the scope of the invention is not limited to the examples or embodiments set forth herein, and one of ordinary skill in the art may use the invention in any number of applications and equivalent devices. Rather, the scope of the invention is limited only by the accompanying claims. Moreover, for any method that is claimed and/or described, whether or not the method is described in conjunction with a flowchart, it should be understood that any explicit or implicit ordering of steps performed during performance of the method does not imply that the steps must be performed in the order presented, but rather the steps may be performed in a different order or in parallel, unless the context dictates otherwise.