US20250321020A1
CONTROL SYSTEM, CONTROL SYSTEM OPERATION METHOD, AND ENVIRONMENT CONTROL SYSTEM
Publication
Application
Classifications
IPC Classifications
CPC Classifications
Applicants
Chicony Electronics Co., Ltd.
Inventors
Yi-Min Hsu, You-Rong Lu
Abstract
A control system, a control system operation method, and an environment control system are provided. The control system operation method includes: providing electrical connections between terminals of an environment regulation system configured externally and connection terminals, where the terminals include a live terminal and at least one load terminal, and the connection terminals include at least one load connection terminal configured to be electrically connected to the at least one load terminal; in response to that a rectifier module receives at least one stolen current transmitted from the connection terminals, rectifying the at least one stolen current by the rectifier module; and in response to an event, executing a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and executing a power-stealing procedure to obtain electrical energy from the connection terminals by a control module.
Figures
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001]This non-provisional application claims priority under 35 U.S.C. § 119(a) to Patent Application No. 113113883 filed in Taiwan, R.O.C. on Apr. 12, 2024, the entire contents of which are hereby incorporated by reference.
BACKGROUND
Technical Field
[0002]The instant disclosure relates to a control system, a control system operation method, and an environment control system, in particular, to a control system, a control system operation method, and an environment control system which are capable of performing power-stealing detection.
Related Art
[0003]The control system of a heating, ventilation and air conditioning (HVAC) system known to the inventor would utilize power stealing technique upon no C wire is electrically connected thereto or under other certain situations. However, if the control system per se has a display or performs several functions to cause the load of the control system to be heavy, malfunction of the relay in the HVAC system may occur easily during the power-stealing procedure.
SUMMARY
[0004]In view of this, according to some embodiments of the instant disclosure, a control system, a control system operation method, and an environment control system are provided to address technical issues which are currently encountered.
[0005]In view of the above, according to some embodiments of the instant disclosure, a control system comprises a plurality of connection terminals, a rectifier module, and a control module. The connection terminals are configured to provide electrical connection for a plurality of terminals of an environment regulation system configured externally, wherein the terminals comprise a live terminal and at least one load terminal, and the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal. The rectifier module is configured to, in response to that the rectifier module receives at least one stolen current transmitted from the connection terminals, rectify the at least one stolen current. The control module is configured to, in response to an event, execute a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and execute a power-stealing procedure to obtain electrical energy from the connection terminals.
[0006]According to some embodiments of the instant disclosure, a control system operation method comprises: providing electrical connections between a plurality of terminals of an environment regulation system configured externally and a plurality of connection terminals, wherein the terminals comprise a live terminal and at least one load terminal, and the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal; in response to that a rectifier module receives at least one stolen current transmitted from the connection terminals, rectifying the at least one stolen current by the rectifier module; and in response to an event, executing a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and executing a power-stealing procedure to obtain electrical energy from the connection terminals by a control module.
[0007]According to some embodiments of the instant disclosure, an environment control system comprises an environment regulation system and a control system. The environment regulation system comprises a plurality of terminals and at least one load, wherein the terminals comprise a live terminal and at least one load terminal, and the at least one load terminal is coupled to the at least one load. The control system comprises a plurality of connection terminals, a rectifier module, and a control module. The connection terminals are configured to provide electrical connection for the terminals of the environment regulation system configured externally, wherein the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal. The rectifier module is configured to, in response to that the rectifier module receives at least one stolen current transmitted from the connection terminals, rectify the at least one stolen current. The control module configured to, in response to an event, execute a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and execute a power-stealing procedure to obtain electrical energy from the connection terminals.
[0008]Based on the above, in the control system, the control system operation method, and the environment control system according to some embodiments of the instant disclosure, at least one stolen current is rectified by the rectifier module, so that electrical energy can be stolen from the environment regulation system through the connection terminals. Stealing electrical energy from the environment regulation system through the connection terminals can reduce the current passing through the connection terminals so as to reduce the possibility of the malfunction of the relay of the environment control system. Moreover, by firstly executing a testing procedure to determine the connection status and the power-stealing range of each of the load connection terminals, not only the load connection terminals with a better power-stealing range can be selected for performing the power-stealing procedure, but also the possibility of the malfunction of the relay of the environment control system can be reduced.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009]The disclosure will become more fully understood from the detailed description given herein below for illustration only, and thus not limitative of the disclosure, wherein:
[0010]
[0011]
[0012]
[0013]
[0014]
[0015]
[0016]
[0017]
[0018]
[0019]
[0020]
[0021]
[0022]
DETAILED DESCRIPTION
[0023]The aforementioned and other technical contents, features and effects of the instant disclosure will be clearly presented in the following detailed description of the embodiments with reference to the drawings. The thickness or size of each component in the drawings is exaggerated, omitted, or schematically expressed for the purpose of understanding and reading by persons having ordinary skills in the art, and the size of each component is not the actual size of the component and is not intended to limit the conditions under which the instant disclosure can be implemented, and thus the size of the component does not have substantive technical meaning. Moreover, it is understood that any structural modifications, changes in proportions, or adjustments in size should still fall within the scope of the technical content disclosed in the instant disclosure without affecting the effects that can be produced and the purposes that can be achieved by the instant disclosure. The same reference numbers will be used throughout the drawings to refer to the same or similar elements. The term “coupled/coupling” mentioned in the following embodiments may refer to any direct or indirect connection.
[0024]
[0025]To allow the control system 100 to be operated normally, the control system 100 needs to steal electrical energy from the environment regulation system 108. The control system 100 comprises a plurality of connection terminals 101, 102-1 to 102-N, 103, a control module 104, and a rectifier module 105, where N is a positive integer. The connection terminal 101 is configured to be electrically connected to the terminal 1081 (the live terminal) of the environment regulation system 108 external to the control system 100. The connection terminals 102-1 to 102-N and 103 are configured to provide electrical connection for the terminals 1082-1 to 1082-N and 1083 of the environment regulation system 108, and thus the connection terminals 102-1 to 102-N are also referred to as the load connection terminals. The connection terminal 103 is configured to be electrically connected to the terminal 1083 of the environment regulation system 108 (the C terminal of the environment regulation system 108), and thus the connection terminal 103 is also referred to as the C wire connection terminal.
[0026]The rectifier module 105 comprises input terminals a, c, b1 to bN. The input terminal a is configured to be coupled to the connection terminal 101, the input terminal c is configured to be coupled to the connection terminal 103, and the input terminals b1 to bN are coupled to the connection terminals 102-1 to 102-N respectively. The control module 104 can respectively control the conduction between the connection terminals 102-1 to 102-N and the input terminals b1 to bN. In the following, the condition that the control module 104 controls the conduction between the input terminal b1 and the connection terminal 102-1 is taken as an example. When the control module 104 controls the conduction between the input terminal b1 and the connection terminal 102-1, the control module 104 and the path formed by the input terminal a and the connection terminal 101 together form a loop so that the connection terminal 101 and the connection terminal 102-1 obtain alternating current from the environment regulation system 108, where the alternating current is referred to as the stolen current. The rectifier module 105 can receive the stolen current from the connection terminal 101 and the connection terminal 102-1. Likewise, when the control module 104 controls the conduction between the input terminal bN and the connection terminal 102-N, the control module 104 and the path formed by the input terminal a and the connection terminal 101 together form a loop so that the rectifier module 105 can receive the stolen current from the connection terminal 101 and the connection terminal 102-N. Further, in the case that not only one input terminal and one connection terminal are conducted with each other, the rectifier module 105 will receive several stolen currents. In some embodiments, the frequencies and the phases of the stolen currents are identical, and the rectifier module 105 rectifies the stolen currents having identical frequencies and phases.
[0027]The control module 104 is configured to control the relays 107-1 to 107-N to be turned on. As shown in
[0028]Refer to
[0029]In the following paragraphs, descriptions and accompanied drawings are provided to show how the cooperation between components of the control system 100 and the control system operation method according to some embodiments of the instant disclosure can be achieved.
[0030]Refer to
[0031]In some embodiments of the instant disclosure, the event is that the control system 100 is booted.
[0032]In some embodiments of the instant disclosure, the event is that the control module 104 detects that the C wire connection terminal (the terminal 103) is not electrically connected.
[0033]In some embodiments of the instant disclosure, when the control module 104 detects that the C wire connection terminal (the terminal 103) is electrically connected, the control module 104 obtains electrical energy through the C wire connection terminal.
[0034]However, even though the control module 104 detects that the C wire connection terminal (the terminal 103) is electrically connected, the control module 104 can obtain electrical energy through a suitable connection terminal among the terminals 101, 102-1 to 102-N according to other demands. In the following embodiments, how to select a suitable connection terminal will be described.
[0035]In some embodiments of the instant disclosure, rectifying the stolen current by the rectifier module 105 comprises the following steps. In response to that the number of the received stolen current is one, the rectifier module 105 rectifies the received stolen current; and in response to that the number of the received stolen current is plural, the rectifier module 105 concurrently rectifies the received stolen currents.
[0036]The description “concurrently rectifies the stolen currents which are received” indicates that the stolen currents are rectified independently by using the same rectification manner at the same time so that the stolen currents which are rectified provide electrical energy parallelly. The rectification manner may be, for example, the full-wave rectification. In the following paragraphs, one circuit embodiment is provided to describe how to rectify the received stolen current in response to that the number of the received stolen current is one and how to concurrently rectify the received stolen current in response to that the number of the received stolen current is plural.
[0037]
[0038]Refer to
[0039]As shown in
[0040]Accordingly, in one or some embodiments, through the operation mentioned above, in the case that the rectifier module 105 receives only one stolen current (for example, the stolen current from the input terminal b1), the rectifier module 105 can perform full-wave rectification on the stolen current through the diode pair corresponding to the stolen current (for example, the diode pair 2031 corresponding to the input terminal b1) and the diode pair 201 corresponding to the input terminal a. In the case that rectifier module 105 receives several stolen currents (for example, the stolen currents from the input terminals b1, b2, bN), the rectifier module 105 can perform full-wave rectification concurrently and independently on the stolen currents through the diode pairs corresponding to the stolen currents (for example, the diode pair 201 corresponding to the input terminal b1, the diode pair 2031 corresponding to the input terminal b2, and the diode pair 203N corresponding to the input terminal bN) and the diode pair 201 corresponding to the input terminal a, so that the rectifier module 105 can concurrently rectify several (two or more) received stolen currents. In the case that the rectifier module 105 receives several stolen currents (for example, the stolen currents from the input terminals b1, b2, bN), because the stolen currents come from the connection terminals 101, 102-1 to 102-N, 103 of the environment regulation system 108, the stolen currents have identical frequencies and phases, thereby allowing the rectified stolen currents can provide electrical energy parallelly.
[0041]
[0042]
[0043]In some embodiments of the instant disclosure, each of the switch modules 401-1 to 401-k has a relay.
[0044]The DC voltage conversion module 402 is configured to convert the DC voltage outputted by the rectifier module 105 into a voltage suitable for the charging module 403. In some embodiments of the instant disclosure, the DC voltage conversion module 402 comprises a buck converter. The charging module 403 is configured to be coupled to the rectifier module 105, the control module 104, and the display module 408. Therefore, in response to that the charging module 403 receives the voltage outputted by the DC voltage conversion module 402, the charging module 403 can output electrical energy for the control module 104 and the display module 408, and in response to that the charging module 403 does not receive the voltage outputted by the DC voltage conversion module 402, the charging module 403 can provide a path to allow the battery module 405 to supply electrical energy for the control module 104 and the display module 408. The battery module 405 is configured to be coupled to the charging module 403, the control module 104, and the display module 408. The DC voltage conversion module 404 is configured to convert the DC voltage outputted to the control module 104 into a voltage suitable for the control module 104, and the voltage suitable for the control module 104 is inputted to the control through 104 through an electrical energy input terminal e of the control module 104. The display module 408 is configured to display a control status information. In some embodiments of the instant disclosure, the DC voltage conversion module 404 comprises a buck converter.
[0045]The toggle module 406 comprises an input terminal PWR, an input terminal VBAT, and a switch input terminal sw. The input terminal PWR of the toggle module 406 receives electrical energy outputted from the charging module 403, the input terminal VBAT of the toggle module 406 receives electrical energy outputted from the battery module 405, and the control module 104 controls the source of electrical energy of the display module 408 through the switch input terminal sw. The DC voltage conversion module 407 is configured to convert the DC voltage which is outputted from the toggle module 406 and to be inputted to the display module 408 into a voltage suitable for the display module 408.
[0046]In the following paragraphs, descriptions and accompanied drawings are provided to show how the cooperation between components of the control system 400 and the control system operation method according to some embodiments of the instant disclosure can be achieved.
[0047]
[0048]In the detecting and controlling step, the current detection modules 106-1 to 106-N detect the current values of the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400) respectively; and the switch modules 401-1 to 401-N control the conduction between the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400) and the rectifier module 105.
[0049]In the step S901, to a to-be-tested connection terminal (for example, the connection terminal 102-1) among the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400), the control module 104 turns on a to-be-tested switch (for example, the switch module 401-1 coupled to the connection terminal 102-1) corresponding to the to-be-tested connection terminal among the switch modules 401-1 to 401-N. The control module 104 extracts at least one load current of the to-be-tested connection terminal, and the control module 104 obtains the connection status and the power-stealing range of the to-be-tested connection terminal according to at least one extracting current value of the at least one load current detected by a to-be-tested current detection module (for example, the current detection module 106-1 coupled to the connection terminal 102-1) corresponding to the to-be-tested connection terminal among the current detection modules 106-1 to 106-N. Wherein, the connection status of the to-be-tested connection terminal is that whether the to-be-tested connection terminal is connected to the terminal of the environment regulation system 108. During the power-stealing procedure, when a current value of a current providing to the rectifier module 105 is less than the power-stealing range of the to-be-tested connection terminal, the load (for example, the load 303-1 corresponding to the terminal 1082-1) in the environment regulation system 108 corresponding to the terminal (for example, the terminal 1082-1) electrically connected to the present connection terminal can be prevented from being turned on mistakenly.
[0050]In this embodiment, when the control system 400 is initializing, the control module 104 takes each of the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400) as the to-be-tested connection terminal mentioned above to obtain the connection status and the power-stealing range of each of the load connection terminals (as mentioned in the steps S902 to S904 below). When the control system 400 is initializing, the control system 400 is just booted and to perform initialization setting on the control system 400. At this moment, the control system 400 does not transmit the control signal to the environment regulation system 108 yet to regulate the environment, and thus each of the load connection terminals (the connection terminals 102-1 to 102-N) can be tested.
[0051]In the step S902, the control module 104 determines whether untested load connection terminal(s) exists among the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400). If the result of the step S902 is yes, the step S903 is executed, and if the result of the step S902 is no, the step S904 is executed. In the step S903, in response to that untested load connection terminal(s) exists among the connection terminals 102-1 to 102-N, the control module 104 selects one of the untested load connection terminals among the connection terminals 102-1 to 102-N as the to-be-tested connection terminal and the operation method goes back to execute the step S901. In the step S904, in response to that untested load connection terminal(s) does not exist among the connection terminals 102-1 to 102-N, the control module 104 exits the testing procedure.
[0052]In the foregoing embodiments, because the testing procedure is executed upon the control system 400 is initializing, and at that time the control system 400 does not transmit the control signal to the environment regulation system 108 yet to turn on the corresponding load to regulate the environment, all the connection terminals 102-1 to 102-N can be tested.
[0053]
[0054]In the embodiment shown in
[0055]In this embodiment, the control module 104 firstly determines whether at least one testable load connection terminal which is not turned on and not tested among the load connection terminals. Then, in response to that the at least one testable load connection terminal exists, the at least one testable load connection terminal is taken as the to-be-tested connection terminal to obtain the connection status and the power-stealing range of each of the testable load connection terminal (as mentioned in the steps S1102 to S1104 below).
[0056]In the step S1102, the control module 104 determines whether at least one load connection terminal which is not turned on and not tested (which can be referred to as the testable load connection terminal) exists among the connection terminals 102-1 to 102-N (the load connection terminals of the control system 400). If the result of the step S1102 is yes, the step S1103 is executed, and if the result of the step S1102 is no, the step S1104 is executed. In the step S1103, in response to that the at least one testable load connection terminal exists among the connection terminals 102-1 to 102-N, the control module 104 selects one of the testable load connection terminals among the connection terminals 102-1 to 102-N as the to-be-tested connection terminal and the operation method goes back to execute the step S1101. In the step S1104, in response to that testable load connection terminal(s) does not exist among the connection terminals 102-1 to 102-N, the control module 104 exits the testing procedure.
[0057]It is noted that, according to some embodiments of the instant disclosure, because the loads corresponding to some connection terminals are turned on, these connection terminals cannot be selected. Upon the control module 104 executes the steps S1101 to S1104, the control module 104 will execute the testing procedure to the untested connection terminals after the loads corresponding to the untested connection terminals are turned off, and the control module 104 will stop executing the testing procedure after all the connection terminals 102-1 to 102-N are tested.
[0058]
[0059]In the step S1202, the control module 104 determines whether at least one power-stealing connection terminal exists among at least one processed load connection terminal which is already processed by the testing procedure in the connection terminals 102-1 to 102-N, wherein the connection status of each of the power-stealing connection terminal is electrically connected, the power-stealing range of the power-stealing connection terminal is greater than or equal to a preset form current value, and a load corresponding to the power-stealing connection terminal in the environment regulation system is not turned on. If the result of the step S1202 is yes, the step S1203 is executed, and if the result of the step S1202 is no, the step S1204 is executed. In the step S1203, in response to that at least one power-stealing connection terminal exists, the control module 104 controls the power-stealing switch(s) corresponding to the power-stealing connection terminal(s) among the switch modules 401-1 to 401-N to be turned on to obtain electrical energy from the power-stealing connection terminal(s). In the step S1204, because no power-stealing connection terminal exists, the control module 104 stops executing the power-stealing procedure. The control module 104 can wait until a new processed load connection terminal is added and then execute the power-stealing procedure.
[0060]
[0061]In the step S1305, the control module 104 adds an increased current value (for example, 10 mA) to the present current value as a next current value, and the control module 104 extracts a next current having the next current value from the to-be-tested connection terminal. In the step S1306, the control module 104 determines whether the current value detected by the to-be-tested current module is the next current value. In the step S1307, in response to that the current value detected by the to-be-tested current detection module is not the next current value or the current value detected by the to-be-tested current detection module is zero, which indicates that the load corresponding to the to-be-tested connection terminal in the environment regulation system 108 is mistakenly turned on, the power-stealing range of the to-be-tested connection terminal is configured as the present current value and the operation method exits the step S901 to the next step or exits the step S1101 to the next step. In the step S1308, in response to that the current value detected by the to-be-tested connection terminal is the next current value, the control module 104 configures the present current value as the next current value and the operation method goes back to execute the step S1305.
[0062]In some embodiments of the instant disclosure, in the step S1304, when the control module 104 determines that the to-be-tested connection terminal is not electrically connected, the control module 104 displays that the to-be-tested connection terminal is not electrically connected on the display module 408 to remind the user of checking the connection condition again.
[0063]
[0064]In some embodiments, in the power-stealing procedure, in response to that the display module 408 is turned off, the control module 104 controls the charging module 403 to charge the battery module 405. That is, the power-stealing procedure comprises the step of controlling the charging module 403, by the control module 104, to charge the battery module 405 in response to the display module 408 being turned off.
[0065]
[0066]
[0067]Based on the above, in the control system, the control system operation method, and the environment control system according to some embodiments of the instant disclosure, at least one stolen current is rectified by the rectifier module, so that electrical energy can be stolen from the environment regulation system through the connection terminals. Stealing electrical energy from the environment regulation system through the connection terminals can reduce the current passing through the connection terminals so as to reduce the possibility of the malfunction of the relay of the environment control system. Moreover, by firstly executing a testing procedure to determine the connection status and the power-stealing range of each of the load connection terminals, not only the load connection terminals with a better power-stealing range can be selected for performing the power-stealing procedure, but also the possibility of the malfunction of the relay of the environment control system can be reduced.
[0068]While the instant disclosure has been described by the way of example and in terms of the preferred embodiments, it is to be understood that the invention need not be limited to the disclosed embodiments. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, the scope of which should be accorded the broadest interpretation so as to encompass all such modifications and similar structures.
Claims
What is claimed is:
1. A control system comprising:
a plurality of connection terminals configured to provide electrical connection for a plurality of terminals of an environment regulation system configured externally, wherein the terminals comprise a live terminal and at least one load terminal, the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal;
a rectifier module configured to, in response to receiving at least one stolen current transmitted from the connection terminals, rectify the at least one stolen current; and
a control module configured to, in response to an event, execute a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and execute a power-stealing procedure to obtain electrical energy from the connection terminals.
2. The control system according to
3. The control system according to
4. The control system according to
5. The control system according to
at least one current detection module configured to detect at least one current value of the at least one load connection terminal respectively; and
at least one switch module arranged between the at least one load connection terminal and the rectifier module;
wherein the test procedure comprises following steps:
(a) executing, to a to-be-tested connection terminal among the at least one load connection terminal: (a1) turning on a to-be-tested switch corresponding to the to-be-tested connection terminal among the at least one switch module; and (a2) extracting at least one load current of the to-be-tested connection terminal and obtaining the connection status and the power-stealing range of the to-be-tested connection terminal according to at least one load current value detected by a to-be-tested current detection module corresponding to the to-be-tested connection terminal among the at least one current detection module.
6. The control system according to
7. The control system according to
determining whether at least one power-stealing connection terminal exists among the at least one load connection terminal, wherein the connection status of each of the at least one power-stealing connection terminal is electrically connected, the power-stealing range of the at least one power-stealing connection terminal is greater than or equal to a preset form current value, and a load corresponding to the at least one power-stealing connection terminal in the environment regulation system is not turned on; and
in response to that the at least one power-stealing connection terminal exists, controlling at least one power-stealing switch corresponding to the at least one power-stealing connection terminal among the at least one switch module to be turned on so as to obtain electrical energy through the at least one power-stealing connection terminal.
8. The control system according to
9. The control system according to
determining whether at least one power-stealing connection terminal exists among at least one processed load connection terminal which is already processed by the test procedure among the at least one load connection terminal, wherein the connection status of each of the at least one power-stealing connection terminal is electrically connected, the power-stealing range of the at least one power-stealing connection terminal is greater than or equal to a preset form current value, and a load corresponding to the at least one power-stealing connection terminal in the environment regulation system is not turned on; and
in response to that the at least one power-stealing connection terminal exists, controlling at least one power-stealing switch corresponding to the at least one power-stealing connection terminal among the at least one switch module to be turned on so as to obtain electrical energy through the at least one power-stealing connection terminal.
10. The control system according to
a display module configured to display a control status information;
a charging module configured to be coupled to the rectifier module, the control module, and the display module; and
a battery module configured to be coupled to the charging module, the control module, and the display module;
wherein the power-stealing procedure comprises:
detecting a supplying current value of each of the at least one power-stealing connection terminal by at least one stolen current detection module corresponding to the at least one power-stealing connection terminal among the at least one current detection module; and
in response to that the supplying current value of an overload connection terminal among the at least one power-stealing connection terminal is greater than the power-stealing range of the overload connection terminal, stopping supplying electrical energy to the display module by the charging module.
11. The control system according to
a display module configured to display a control status information;
a charging module configured to be coupled to the rectifier module, the control module, and the display module; and
a battery module configured to be coupled to the charging module, the control module, and the display module;
wherein the power-stealing procedure comprises:
in response to that the display module is turned off, controlling the charging module to charge the battery module.
12. The control system according to
(a21) taking a preset current value as a present current value;
(a22) extracting a present current having the present current value from the to-be-tested connection terminal; in response to that a current value detected by the to-be-tested current detection module corresponding to the to-be-tested connection terminal among the at least one current detection module is zero, determining that the to-be-tested connection terminal is not electrically connected; and
(a23) adding an increased current value to the present current value as a next current value, extracting a next current having the next current value from the to-be-tested connection terminal, and in response to that the current value detected by the to-be-tested current detection module is not the next current value, configuring the power-stealing range of the to-be-tested connection terminal as the present current value; in response to that the current value detected by the to-be-tested current detection module is the next current value, configuring the present current value as the next current value and executing the step (a23).
13. A control system operation method comprising:
providing electrical connections between a plurality of terminals of an environment regulation system configured externally and a plurality of connection terminals, wherein the terminals comprise a live terminal and at least one load terminal, and the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal;
in response to that a rectifier module receives at least one stolen current transmitted from the connection terminals, rectifying the at least one stolen current by the rectifier module; and
in response to an event, executing a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal by a control module and executing a power-stealing procedure to obtain electrical energy from the connection terminals by the control module.
14. The control system operation method according to
15. The control system operation method according to
16. The control system operation method according to
detecting at least one current value of the at least one load connection terminal by at least one current detection module respectively; and
controlling a conduction between the at least one load connection terminal and the rectifier module by at least one switch module;
wherein the test procedure comprises following steps:
(a) executing, to a to-be-tested connection terminal among the at least one load connection terminal: (a1) turning on a to-be-tested switch corresponding to the to-be-tested connection terminal among the at least one switch module; and (a2) extracting at least one load current of the to-be-tested connection terminal and obtaining the connection status and the power-stealing range of the to-be-tested connection terminal according to at least one load current value detected by a to-be-tested current detection module corresponding to the to-be-tested connection terminal among the at least one current detection module.
17. The control system operation method according to
18. The control system operation method according to
determining whether at least one power-stealing connection terminal exists among the at least one load connection terminal, wherein the connection status of each of the at least one power-stealing connection terminal is electrically connected, the power-stealing range of the at least one power-stealing connection terminal is greater than or equal to a preset form current value, and a load corresponding to the at least one power-stealing connection terminal in the environment regulation system is not turned on; and
in response to that the at least one power-stealing connection terminal exists, controlling at least one power-stealing switch corresponding to the at least one power-stealing connection terminal among the at least one switch module to be turned on so as to obtain electrical energy through the at least one power-stealing connection terminal.
19. The control system operation method according to
20. The control system operation method according to
determining whether at least one power-stealing connection terminal exists among at least one processed load connection terminal which is already processed by the test procedure among the at least one load connection terminal, wherein the connection status of each of the at least one power-stealing connection terminal is electrically connected, the power-stealing range of the at least one power-stealing connection terminal is greater than or equal to a preset form current value, and a load corresponding to the at least one power-stealing connection terminal in the environment regulation system is not turned on; and
in response to that the at least one power-stealing connection terminal exists, controlling at least one power-stealing switch corresponding to the at least one power-stealing connection terminal among the at least one switch module to be turned on so as to obtain electrical energy through the at least one power-stealing connection terminal.
21. The control system operation method according to
detecting a supplying current value of each of the at least one power-stealing connection terminal by at least one stolen current detection module corresponding to the at least one power-stealing connection terminal among the at least one current detection module; and
in response to that the supplying current value of an overload connection terminal among the at least one power-stealing connection terminal is greater than the power-stealing range of the overload connection terminal, stopping supplying electrical energy to a display module by a charging module.
22. The control system operation method according to
in response to that a display module is turned off, controlling a charging module to charge a battery module.
23. The control system operation method according to
(a21) taking a preset current value as a present current value;
(a22) extracting a present current having the present current value from the to-be-tested connection terminal; in response to that a current value detected by the to-be-tested current detection module corresponding to the to-be-tested connection terminal among the at least one current detection module is zero, determining that the to-be-tested connection terminal is not electrically connected; and
(a23) adding an increased current value to the present current value as a next current value, extracting a next current having the next current value from the to-be-tested connection terminal, and in response to that the current value detected by the to-be-tested current detection module is not the next current value, configuring the power-stealing range of the to-be-tested connection terminal as the present current value; in response to that the current value detected by the to-be-tested current detection module is the next current value, configuring the present current value as the next current value and executing the step (a23).
24. An environment control system comprising:
an environment regulation system comprising a plurality of terminals and at least one load, wherein the terminals comprise a live terminal and at least one load terminal, and the at least one load terminal is coupled to the at least one load; and
a control system comprising:
a plurality of connection terminals configured to provide electrical connection for the terminals of the environment regulation system, wherein the connection terminals comprise at least one load connection terminal configured to be electrically connected to the at least one load terminal;
a rectifier module configured to, in response to receiving at least one stolen current transmitted from the connection terminals, rectify the at least one stolen current; and
a control module configured to, in response to an event, execute a test procedure to determine a connection status and a power-stealing range of each of the at least one load connection terminal and execute a power-stealing procedure to obtain electrical energy from the connection terminals.