CN220553663U - Intelligent socket equipment based on load monitoring - Google Patents

Abstract

The utility model discloses an intelligent socket device based on load monitoring, which comprises: the control module forms actual current voltage curve information according to the curve information of each of the live wire current transformer, the zero line current transformer and the live wire voltage sampler, compares the actual current voltage curve information with the standard current voltage curve information from the storage module, and generates a trigger signal for controlling the on-off of the circuit on-off switching module when the difference of comparison is larger than a threshold value; the storage module is used for storing standard current-voltage curve information and threshold information in a normal range; the cloud server is used for receiving the electricity load using state and the line state transmitted by the wireless transmission module. The utility model improves the monitoring range and safety, thereby reducing the labor cost and the probability of electric injury.

Description

Intelligent socket equipment based on load monitoring

Technical Field

The utility model belongs to the technical field of intelligent electricity utilization, and particularly relates to an intelligent socket device based on load monitoring.

Background

As the types and numbers of electric appliances in building lines are increasing, the electric safety performance of the electric appliances and lines in the building is gradually reduced along with the increase of the service time, and the occurrence frequency of fire caused by the aging of the lines or the improper use of the electric appliances is also continuously increased. The existing power socket has a simple function, and the socket is one of the common accessories in a building, if the socket can be intelligentized, more control functions can be provided for the socket, so that the daily life of people can be enriched. How to assist in the detection and maintenance of faulty equipment by means of sockets, is a direction of effort by those skilled in the art in order to save costs and improve safety.

Disclosure of Invention

The utility model mainly aims to provide the intelligent socket equipment based on the load monitoring, which improves the monitoring range and the safety, thereby reducing the labor cost and the probability of electric injury.

In order to achieve the above purpose, the utility model adopts the following technical scheme: the intelligent socket device based on load monitoring comprises a socket body, a circuit on-off switching module, a live wire pin and a zero wire pin which are positioned on one end face of the socket body and used for being connected with a commercial power line, and a live wire jack and a zero wire jack which are positioned on the other end face of the socket body and used for being connected with an electric load, wherein the live wire pin and the zero wire pin are connected with the circuit on-off switching module through an input side power line, and the circuit on-off switching module is connected with the live wire jack and the zero wire jack through an output side power line; further comprises:

the live wire current transformer is arranged on a live wire in the power wire and is used for measuring the current on the live wire so as to generate a corresponding current induction signal;

the zero line current transformer is arranged on a zero line in the power line and is used for measuring the current on the zero line so as to generate a corresponding current induction signal;

the live wire voltage transformer is arranged on a live wire in the power wire and is used for measuring the voltage on the live wire so as to generate a corresponding voltage induction signal;

the live wire current sampler samples a current induction signal from the live wire current transformer according to a set time sequence, so that live wire current curve information is obtained;

the zero line current sampler samples a current induction signal from the zero line current transformer according to a set time sequence, so that zero line current curve information is obtained;

the live wire voltage sampler samples a voltage induction signal from the live wire voltage transformer according to a set time sequence, so that live wire voltage curve information is obtained;

the control module forms actual current voltage curve information according to the curve information from each of the live wire current sampler, the zero line current sampler and the live wire voltage sampler, compares the actual current voltage curve information with the standard current voltage curve information from the storage module, and generates a trigger signal for controlling the on-off of the circuit on-off switching module when the comparison difference is larger than a threshold value;

the storage module is used for storing standard current-voltage curve information and threshold information in a normal range;

the wireless transmission module is used for transmitting the using state and the line state of the power load from the control module to the cloud server;

the cloud server is used for receiving the electricity load using state and the line state transmitted by the wireless transmission module.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, the circuit on-off switching module further comprises an optocoupler connected in series and a relay arranged on a live wire in the input side power line.

2. In the above scheme, the wireless transmission module is one or a combination of any two of a WiFi communication module, a bluetooth communication module and a Zigbee communication module.

3. In the scheme, the end faces with the live wire pins and the zero wire pins are arranged opposite to the end faces with the live wire jacks and the zero wire jacks.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages:

the intelligent socket equipment based on load monitoring not only can monitor whether the use state of the load electric appliance is abnormal or not and the power consumption amount by setting parameters when supplying power to the electric appliance, so that diagnosis and fault early warning can be carried out on the load equipment; the use state of the load electrical appliance and the state of the circuit can be transmitted to the remote cloud server through the wireless network, so that the monitoring range and safety are improved, and the cost and the probability of electrical injury are reduced.

Drawings

Fig. 1 is a schematic structural diagram of an intelligent socket device according to the present utility model under a view angle;

fig. 2 is a schematic structural diagram of the smart jack device according to the present utility model under another view angle;

fig. 3 is a circuit frame diagram of the intelligent socket device based on load monitoring of the present utility model.

In the above figures: 1. a socket body; 2. a circuit on-off switching module; 3. a mains supply line; 41. a live wire pin; 42. a zero line pin; 5. an electrical load; 61. a live wire jack; 62. zero line jack; 71. an input-side power supply line; 72. an output-side power supply line; 73. a firing line; 74. a zero line; 8. a live wire current transformer; 9. a zero line current transformer; 10. a live wire voltage transformer; 11. a live wire current sampler; 12. a zero line current sampler; 13. a live wire voltage sampler; 14. a control module; 15. a storage module; 16. a wireless transmission module; 17. an optical coupler; 18. a relay; 19. and the cloud server.

Detailed Description

In the description of this patent, it should be noted that, directions or positional relationships indicated by terms such as "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., are based on directions or positional relationships shown in the drawings, are merely for convenience of description and simplification of description, and do not indicate or imply that the apparatus or element in question must have a specific direction, be configured and operated in a specific direction, and thus should not be construed as limiting the utility model; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in this patent will be understood by those of ordinary skill in the art in a specific context.

Example 1: the intelligent socket device based on load monitoring comprises a socket body 1, a circuit on-off switching module 2, a live wire pin 41 and a neutral wire pin 42 which are positioned on one end face of the socket body 1 and used for being connected with a commercial power line 3, and a live wire jack 61 and a neutral wire jack 62 which are positioned on the other end face of the socket body 1 and used for being connected with an electric load 5, wherein the live wire pin 41 and the neutral wire pin 42 are connected with the circuit on-off switching module 2 through an input side power line 71, and the circuit on-off switching module 2 is connected with the live wire jack 61 and the neutral wire jack 62 through an output side power line 72; further comprises:

a live wire current transformer 8, which is installed on a live wire 73 in the power line and is used for measuring the current on the live wire so as to generate a corresponding current induction signal;

a zero line current transformer 9, which is installed on a zero line 74 in the power line and is used for measuring the current on the zero line so as to generate a corresponding current induction signal;

a live wire voltage transformer 10, which is installed on a live wire 73 in the power line and is used for measuring the voltage on the live wire so as to generate a corresponding voltage induction signal;

the live wire current sampler 11 samples a current induction signal from the live wire current transformer 8 according to a set time sequence, so as to obtain live wire current curve information;

a zero line current sampler 12 that samples the current induction signal from the zero line current transformer 9 according to a set timing sequence, thereby obtaining zero line current curve information;

the live wire voltage sampler 13 samples the voltage induction signal from the live wire voltage transformer 10 according to a set time sequence, so as to obtain live wire voltage curve information;

the control module 14 forms actual current-voltage curve information according to the curve information from each of the live wire current sampler 11, the zero line current sampler 12 and the live wire voltage sampler 13, compares the actual current-voltage curve information with the standard current-voltage curve information from the storage module 15, and generates a trigger signal for controlling the on-off of the circuit on-off switching module 2 when the comparison difference is greater than a threshold value;

the storage module 15 is used for storing standard current voltage curve information and threshold value information in a normal range;

the wireless transmission module 16 is used for transmitting the use state and the line state of the electric load 5 from the control module 14 to the cloud server 19;

the cloud server 19 is configured to receive the usage status and the line status of the power load 5 transmitted by the wireless transmission module 16.

The circuit on-off switching module 2 further comprises an optocoupler 17 and a relay 18 which are connected in series and are arranged on a live wire 73 in the input side power line 71; the wireless transmission module 16 is a combination of a WiFi communication module and a Zigbee communication module.

Example 2: the intelligent socket device based on load monitoring comprises a socket body 1, a circuit on-off switching module 2, a live wire pin 41 and a neutral wire pin 42 which are positioned on one end face of the socket body 1 and used for being connected with a commercial power line 3, and a live wire jack 61 and a neutral wire jack 62 which are positioned on the other end face of the socket body 1 and used for being connected with an electric load 5, wherein the live wire pin 41 and the neutral wire pin 42 are connected with the circuit on-off switching module 2 through an input side power line 71, and the circuit on-off switching module 2 is connected with the live wire jack 61 and the neutral wire jack 62 through an output side power line 72; further comprises:

a live wire current transformer 8, which is installed on a live wire 73 in the power line and is used for measuring the current on the live wire so as to generate a corresponding current induction signal;

a zero line current transformer 9, which is installed on a zero line 74 in the power line and is used for measuring the current on the zero line so as to generate a corresponding current induction signal;

a live wire voltage transformer 10, which is installed on a live wire 73 in the power line and is used for measuring the voltage on the live wire so as to generate a corresponding voltage induction signal;

the live wire current sampler 11 samples a current induction signal from the live wire current transformer 8 according to a set time sequence, so as to obtain live wire current curve information;

a zero line current sampler 12 that samples the current induction signal from the zero line current transformer 9 according to a set timing sequence, thereby obtaining zero line current curve information;

the live wire voltage sampler 13 samples the voltage induction signal from the live wire voltage transformer 10 according to a set time sequence, so as to obtain live wire voltage curve information;

the control module 14 forms actual current-voltage curve information according to the curve information from each of the live wire current sampler 11, the zero line current sampler 12 and the live wire voltage sampler 13, compares the actual current-voltage curve information with the standard current-voltage curve information from the storage module 15, and generates a trigger signal for controlling the on-off of the circuit on-off switching module 2 when the comparison difference is greater than a threshold value;

the storage module 15 is used for storing standard current voltage curve information and threshold value information in a normal range;

the wireless transmission module 16 is used for transmitting the use state and the line state of the electric load 5 from the control module 14 to the cloud server 19;

the cloud server 19 is configured to receive the usage status and the line status of the power load 5 transmitted by the wireless transmission module 16.

The wireless transmission module 16 is a combination of a WiFi communication module and a bluetooth communication module; the end surfaces of the live wire pins 41 and neutral wire pins 42 are opposite to the end surfaces of the live wire insertion holes 61 and neutral wire insertion holes 62.

When the intelligent socket equipment based on the load monitoring is adopted, the power is supplied to the electric appliance, and meanwhile, whether the use state of the load electric appliance is abnormal or not and the power consumption amount can be monitored through setting parameters, so that diagnosis and fault early warning can be carried out on the load equipment; the use state of the load electrical appliance and the state of the circuit can be transmitted to the remote cloud server through the wireless network, so that the monitoring range and safety are improved, and the cost and the probability of electrical injury are reduced.

The above embodiments are provided to illustrate the technical concept and features of the present utility model and are intended to enable those skilled in the art to understand the content of the present utility model and implement the same, and are not intended to limit the scope of the present utility model. All equivalent changes or modifications made in accordance with the spirit of the present utility model should be construed to be included in the scope of the present utility model.

Claims (4)

1. Intelligent socket equipment based on load control, its characterized in that: the socket comprises a socket body (1), a circuit on-off switching module (2), a live wire pin (41) and a zero wire pin (42) which are positioned on one end face of the socket body (1) and used for being connected with a commercial power line (3), and a live wire jack (61) and a zero wire jack (62) which are positioned on the other end face of the socket body (1) and used for being connected with an electric load (5), wherein the live wire pin (41), the zero wire pin (42) and the circuit on-off switching module (2) are connected through an input side power line (71), and the circuit on-off switching module (2) is connected with the live wire jack (61) and the zero wire jack (62) through an output side power line (72); further comprises:

the live wire current transformer (8) is arranged on a live wire (73) in the power line and is used for measuring the current on the live wire so as to generate a corresponding current induction signal;

a zero line current transformer (9) which is arranged on a zero line (74) in the power line and is used for measuring the current on the zero line so as to generate a corresponding current induction signal;

the live wire voltage transformer (10) is arranged on a live wire (73) in the power line and is used for measuring the voltage on the live wire so as to generate a corresponding voltage induction signal;

the live wire current sampler (11) is used for sampling a current induction signal from the live wire current transformer (8) according to a set time sequence, so that live wire current curve information is obtained;

the zero line current sampler (12) is used for sampling a current induction signal from the zero line current transformer (9) according to a set time sequence so as to obtain zero line current curve information;

the live wire voltage sampler (13) is used for sampling voltage induction signals from the live wire voltage transformer (10) according to a set time sequence, so that live wire voltage curve information is obtained;

the control module (14) forms actual current-voltage curve information according to the curve information of each of the live wire current sampler (11), the zero line current sampler (12) and the live wire voltage sampler (13), compares the actual current-voltage curve information with the standard current-voltage curve information of the storage module (15), and generates a trigger signal for controlling the on-off of the circuit on-off switching module (2) when the compared difference is larger than a threshold value;

the storage module (15) is used for storing standard current-voltage curve information and threshold value information in a normal range;

the wireless transmission module (16) is used for transmitting the use state and the line state of the power utilization load (5) from the control module (14) to the cloud server (19);

the cloud server (19) is used for receiving the use state and the line state of the power utilization load (5) transmitted by the wireless transmission module (16).

2. The load monitoring-based smart jack device of claim 1, wherein: the circuit on-off switching module (2) further comprises an optocoupler (17) connected in series and a relay (18) arranged on a live wire (73) in the input side power line (71).

3. The load monitoring-based smart jack device of claim 1, wherein: the wireless transmission module (16) is one or the combination of any two of a WiFi communication module, a Bluetooth communication module and a Zigbee communication module.

4. The load monitoring-based smart jack device of claim 1, wherein: the end surfaces of the live wire pins (41) and the neutral wire pins (42) are opposite to the end surfaces of the live wire jacks (61) and the neutral wire jacks (62).