CN112186507A - One-button sequential control method for intelligent switch cabinet - Google Patents

Abstract

The invention relates to the technical field of switch equipment, in particular to a one-key sequential control method for an intelligent switch cabinet; the system comprises the following steps of S1: acquiring the insertion depth, the flowing current value, the pressure and the temperature of a plum blossom contact of the circuit breaker; step S2, signal comparison: comparing the insertion depth of the plum blossom-shaped contact of the circuit breaker with the set value of the depth, and comparing the value of the current flowing through the circuit breaker with the set value of the current; step S3, drive telemetry: when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, driving a working position remote measurement criterion of a circuit breaker handcart; when the current value flowing through the circuit breaker is larger than the current set value, driving a remote measurement criterion of the closing state of the circuit breaker; step S4, judging in place: selecting a normally open signal of an auxiliary point in a closing state of the circuit breaker as a position remote signaling criterion; the method adopts 'position remote signaling criterion + remote measuring criterion', and judges whether the equipment is operated in place or not by the corresponding change of the indication of two non-identical principles.

Description

One-button sequential control method for intelligent switch cabinet

Technical Field

The invention relates to the technical field of switch equipment, in particular to a one-key sequential control method for an intelligent switch cabinet.

Background

The switch device is one of the important components of electric energy distribution, and plays an important role in the modern power grid engineering construction. The medium and low voltage switch equipment is widely applied to the field of power supply and distribution, and is important equipment for controlling power equipment, controlling circuit opening and closing and protecting in a power system. The safety, stability and reliability of its operation will directly affect the quality of the consumer power supply.

In recent years, the number of transformer substations which are put into use is increased year by year, the complexity of equipment operation in the transformer substations is increased day by day, the workload of related operation and maintenance personnel is increased, and the existing control method cannot meet the requirements of power grid development and operation and maintenance. Therefore, in order to ensure the normal operation of the switch cabinet and the power supply quality of users, the real-time monitoring and intelligent control transformation of the operation state of the switch cabinet are imperative.

The intelligent switch cabinet one-key sequence control technology can automatically check the running state of equipment before running, the switch cabinet is intelligent in operation, the working strength of maintenance personnel is reduced, and the intelligent switch cabinet one-key sequence control technology has profound and important significance for stable running of substation equipment.

The one-key sequential control is an operation mode of the switching operation of the transformer substation, and can realize the prefabrication of operation item software, the modular construction of operation tasks, the automatic judgment of equipment states, the intelligent check of error-proof interlocking, the one-key starting of operation steps and the automatic sequential execution of operation processes. When the double confirmation is that the equipment is operated remotely, at least two different principles or different source indications are correspondingly changed, and all the indications are correspondingly changed at the same time, so that the equipment can be confirmed to be operated in place.

Disclosure of Invention

The invention aims to provide a one-button sequential control method for an intelligent switch cabinet, which adopts 'position remote signaling criterion + remote measuring criterion' to judge whether equipment is operated in place or not by correspondingly changing two indications with different principles.

In order to solve the technical problems, the invention provides the following technical scheme:

a one-button sequential control method for an intelligent switch cabinet comprises the following steps:

step S1, signal acquisition: acquiring the insertion depth, the flowing current value, the pressure and the temperature of a plum blossom contact of the circuit breaker;

step S2, signal comparison: comparing the insertion depth of the plum blossom-shaped contact of the circuit breaker with the set value of the depth, and comparing the value of the current flowing through the circuit breaker with the set value of the current;

step S3, drive telemetry: when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, driving a remote measurement criterion of the working position of the handcart; when the current value flowing through the circuit breaker is larger than the current set value, driving a remote measurement criterion of the closing state of the circuit breaker;

step S4, judging in place: selecting a normally open signal of an auxiliary point in a closing state of the circuit breaker as a position remote signaling criterion, and determining 'the position remote signaling criterion + a remote measuring criterion' when the circuit breaker is opened and closed; a normally open signal of an auxiliary point of a working position of a circuit breaker handcart is selected as a position remote signaling criterion, and the working position of the handcart confirms the 'position remote signaling criterion + remote measurement criterion'.

Further, the insertion depth of the circuit breaker tulip contact in the step S1 is collected through an infrared ranging module, and the method specifically includes the following steps:

a1, measuring the distance from the infrared distance measurement module to the fixed contact copper bar;

and A2, calculating the insertion depth of the tulip contact according to the distance from the infrared distance measuring module to the copper bar of the fixed contact, the external dimension of the fixed contact and the installation position of the intelligent sensing ring.

Further, the current value that circuit breaker plum blossom contact flowed through passes through load perception module collection, specifically includes the following step:

b1, detecting an electromagnetic field intensity signal at the plum blossom contact of the circuit breaker;

and step B2, calculating the current value flowing through the breaker according to the electromagnetic field intensity signal.

Further, the pressure of circuit breaker plum blossom contact is gathered through pressure perception module, specifically includes following step:

step C1, detecting a pressure analog signal of the plum blossom contact spring;

and step C2, converting the pressure analog signal into a pressure value.

Further, the temperature of the plum blossom contact of the circuit breaker is collected through a temperature collection module, and the method specifically comprises the following steps:

d1, detecting a temperature signal of the tulip contact;

and D2, converting the temperature signal into a temperature value.

Further, step S1 carries out signal acquisition through intelligent perception ring, intelligent perception ring includes equipment power module, system host system, infrared ranging module, load perception module, pressure perception module, temperature acquisition module, wireless communication module, system host system is used for gathering the insertion depth of circuit breaker plum blossom contact, the current value that flows through, pressure, temperature pass through wireless communication module carries to intelligent subassembly.

Furthermore, the intelligent sensing ring is installed on a plum blossom contact of the circuit breaker.

Further, the step S2 and the step S3 are used for signal comparison and drive remote measurement through an intelligent assembly, and the intelligent assembly transmits hard contact signals of the switching-on and switching-off state of the circuit breaker and the working position of the circuit breaker handcart to a one-key sequence control host.

Furthermore, the intelligent assembly comprises a handcart working position relay, a breaker closing state relay, a comparison unit and a driving unit, and when the comparison unit judges that the insertion depth of the plum blossom contact of the breaker is greater than a depth set value, the driving unit drives the handcart working position relay to act; when the comparison unit judges that the current value flowing through the circuit breaker is larger than the current set value, the driving unit drives the circuit breaker to close the relay to act.

Compared with the prior art, the technical scheme has the following advantages:

the invention relates to a one-button sequential control method for an intelligent switch cabinet, which adopts 'position remote signaling criterion + remote measuring criterion', and judges whether equipment is operated in place or not by correspondingly changing two indications with different principles.

Drawings

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

Fig. 1 is a structural block diagram of a one-button sequential control system of an intelligent switch cabinet according to the present invention;

FIG. 2 is an electrical schematic diagram of the current-taking circuit according to the present invention;

fig. 3 is a schematic block diagram of a load sensing module according to the present invention.

In the figure: 1. an intelligent sensing ring; 11. a device power supply module; 111. taking a power ring; 112. a power taking loop; 113. a super capacitor; 12. a system main control module; 13. an infrared ranging module; 131. an infrared distance measuring unit; 132. an insertion depth calculation unit; 14. a load sensing module; 141. a magnetoresistive element; 142. a load calculation unit; 15. a pressure sensing module; 151. a ceramic pressure sensor; 152. a pressure calculation unit; 16. a temperature acquisition module; 161. a temperature sensing element; 162. a temperature processing unit; 17. a wireless communication module; 2. an intelligent component; 21. a handcart working position relay; 22. a breaker closing state relay; 23. a comparison unit; 24. a drive unit; 3. a key sequence control host.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, specific details are set forth in order to provide a thorough understanding of the present invention. The invention can be implemented in a number of ways different from those described herein and similar generalizations can be made by those skilled in the art without departing from the spirit of the invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.

Example 1

The invention provides a specific implementation mode of an intelligent switch cabinet one-button sequential control method, which comprises the following steps of:

step S1, signal acquisition: acquiring the insertion depth, the flowing current value, the pressure and the temperature of a plum blossom contact of the circuit breaker;

step S2, signal comparison: comparing the insertion depth of the plum blossom-shaped contact of the circuit breaker with the set value of the depth, and comparing the value of the current flowing through the circuit breaker with the set value of the current;

step S3, drive telemetry: when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, driving a working position remote measurement criterion of a circuit breaker handcart; when the current value flowing through the tulip contact is larger than the current set value, driving a remote measurement criterion of the closing state of the circuit breaker;

step S4, judging in place: selecting a normally open signal of an auxiliary point in a closing state of the circuit breaker as a position remote signaling criterion, and determining 'the position remote signaling criterion + a remote measuring criterion' when the circuit breaker is opened and closed; and selecting a normally open signal of an auxiliary point at the working position of the circuit breaker handcart as a position remote signaling criterion, and confirming the 'position remote signaling criterion + remote measurement criterion' data of the working position of the circuit breaker handcart.

As shown in fig. 1 to 3, the insertion depth of the breaker tulip contact in step S1 is collected by the infrared ranging module 13, and the method specifically includes the following steps:

a1, measuring the distance from the infrared distance measuring module 13 to the fixed contact copper bar;

and A2, calculating the insertion depth of the tulip contact according to the distance from the infrared distance measuring module 13 to the fixed contact copper bar, the external dimension of the fixed contact and the installation position of the intelligent sensing ring 1.

The current value that circuit breaker plum blossom contact flowed through passes through load perception module 14 and gathers, specifically includes the following steps:

b1, detecting an electromagnetic field intensity signal at the plum blossom contact of the circuit breaker;

and step B2, calculating the current value flowing through the breaker according to the electromagnetic field intensity signal.

Wherein, the pressure of circuit breaker plum blossom contact is gathered through pressure perception module 15, specifically includes following step:

step C1, detecting a pressure analog signal of the tulip contact;

and step C2, converting the pressure analog signal into a pressure value.

The circuit breaker plum blossom contact spring can be detected, and the accident caused by the aging of the spring can be early warned in advance.

The temperature of the plum blossom contact of the circuit breaker is collected through a temperature collecting module 16, and the method specifically comprises the following steps:

d1, detecting a temperature signal of the tulip contact;

and D2, converting the temperature signal into a temperature value.

The temperature of the circuit breaker can be detected, and the accident of temperature rise caused by aging can be early warned in advance.

Wherein, step S1 carries out signal acquisition through intelligent perception ring 1, intelligent perception ring 1 includes equipment power module 11, system host system 12, infrared ranging module 13, load perception module 14, pressure perception module 15, temperature acquisition module 16, wireless communication module 17, system host system 12 is used for gathering the insertion depth of circuit breaker plum blossom contact, the current value that flows through, pressure, temperature and passes through wireless communication module 17 carries to intelligent subassembly 2.

By adopting the intelligent sensing ring 1, when a circuit breaker handcart enters and exits the switch cabinet or the circuit breaker is switched on and off, the real-time states of the handcart working position relay 21 and the circuit breaker switching-on state relay 22 are actively updated. The defect that the acquisition of one-key sequence control confirmation signals of the original switch cabinet needs to wait for the sequence control host to send sequence control instructions to start acquiring the second judgment data state is overcome.

Wherein, intelligence perception ring 1 installs on the plum blossom contact of circuit breaker.

The switch cabinet can be moved out along with the circuit breaker handcart during maintenance, and daily maintenance is facilitated.

The step S2 and the step S3 are used for signal comparison and drive remote measurement through the intelligent assembly 2, and the intelligent assembly 2 transmits hard contact signals of the on-off state of the circuit breaker and the working position of the circuit breaker handcart to the one-key sequence control host 3.

The intelligent assembly 2 comprises a handcart working position relay 21, a breaker closing state relay 22, a comparison unit 23 and a driving unit 24, wherein when the comparison unit 23 judges that the insertion depth of a breaker tulip contact is greater than a depth set value, the driving unit 24 drives the handcart working position relay 21 to act; when the comparing unit 23 determines that the current value flowing through the circuit breaker is greater than the current set value, the driving unit 24 drives the circuit breaker closing state relay 22 to operate.

The one-key sequence control method for the intelligent switch cabinet can be realized through the one-key sequence control system for the intelligent switch cabinet. As shown in fig. 1-3, the one-button sequential control system for the intelligent switch cabinet comprises a one-button sequential control host 3, an intelligent assembly 2 and an intelligent sensing ring 1 which are connected in sequence, the intelligent sensing ring 1 comprises an equipment power supply module 11, a system main control module 12, an infrared distance measuring module 13, a load sensing module 14, a pressure sensing module 15, a temperature acquisition module 16 and a wireless communication module 17, the infrared distance measuring module 13 is used for monitoring the insertion depth of the plum blossom contact of the circuit breaker, the load sensing module 14 is used for monitoring the current value flowing through the circuit breaker, the pressure sensing module 15 is used for monitoring the pressure of the circuit breaker, the temperature collecting module 16 is used for monitoring the temperature of the circuit breaker, the system main control module 12 is used for collecting the insertion depth, the flowing current value, the pressure and the temperature of the plum blossom contact of the circuit breaker and transmitting the current value, the pressure and the temperature to the intelligent assembly 2 through the wireless communication module 17; the intelligent assembly 2 comprises a handcart working position relay 21, a breaker closing state relay 22, a comparison unit 23 and a driving unit 24, wherein the comparison unit 23 is used for comparing the insertion depth and the depth set value of a breaker plum blossom contact and comparing the current value flowing through the breaker and the current set value; when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, the driving unit 24 is used for driving the handcart working position relay 21 to act; when the current value flowing through the tulip contact is greater than the current set value, the driving unit 24 is used for driving the breaker closing state relay 22 to act.

The device power supply module 11 is connected to the system main control module 12, and includes a power taking loop 111, a power taking loop 112, and a super capacitor 113.

Here, the voltage regulator D5 realizes dual protection of start-up protection and short-circuit current surge for the power-taking circuit at the moment of power-on of the power-taking circuit 112, and when the input voltage exceeds the set value of 6.2V, the voltage regulator D5 is directly turned on to short-circuit the subsequent circuit and protect the subsequent circuit from being damaged. When the starting input voltage is less than the set value of 6.2V, the circuit is normally started, and when the rectified small bus voltage exceeds the set value of 4.48V, the capacitor C8 is connected into the circuit to further filter the rectified waveform; when the rectified small bus voltage exceeds a set value of 4.76V, the backup super capacitor is connected to a main power circuit; when the rectified small bus voltage exceeds the set value of 5.28V, Q8 is conducted, the charging circuit before Q8 is short-circuited, the rear-stage circuit is powered by C7 and C8, and when the rectified small bus voltage is less than 5.28V, Q8 is cut off, the rectifying circuit charges the subsequent circuits.

Wherein, the electricity taking ring 111 is made of permalloy materials.

The permalloy is selected as a magnetic material and matched with the design of the unique power taking loop 112 of the invention, so that the functions of low-current power taking (minimum 5A starting), large-current protection technology and short-time short-circuit current impact prevention are realized.

The infrared ranging module 13 includes an infrared ranging unit 131 and an insertion depth calculating unit 132, which are connected in sequence, the infrared ranging unit 131 is configured to measure a distance from the intelligent sensing ring 1 to the fixed contact copper bar, and the insertion depth calculating unit 132 is configured to calculate an insertion depth of the tulip contact according to the distance from the intelligent sensing ring 1 to the fixed contact copper bar, an external dimension of the fixed contact, and an installation position of the intelligent sensing ring 1.

Here, the infrared ranging module 13 starts a signal:

1. a circuit breaker test position signal A and a working position signal B are defined, a falling edge signal A can be used as a starting signal of intelligent sensing ring ranging, and a rising edge of B and a signal phase B or delay of 5s can be used as an ending signal of intelligent sensing ring ranging.

2. If the signal that A & B is 1 appears, intelligent component 2 indicates that the circuit breaker is not in the correct position, delay 5S is used as the finishing signal of intelligent perception ring 1 ranging, the falling edge appears in the A & B signal, the rising edge of the B signal starts the starting signal of intelligent perception ring 1 ranging, and the rising edge of B and the B signal phase or delay 5S are used as the finishing signal of intelligent perception ring 1 ranging.

3. After the one-key sequence control host 3 sends a sequence control instruction, the infrared ranging module 13 starts a starting signal of the intelligent sensing ring 1 for ranging; and taking the phase or delay of 5s between the rising edge of B and the B signal as an end signal of the intelligent sensing ring 1 ranging.

The load sensing module 14 includes a magnetoresistive element 141 and a load calculating unit 142, which are connected in sequence, where the magnetoresistive element 141 is configured to detect an electromagnetic field strength signal, and the load calculating unit 142 is configured to calculate a current value flowing through the circuit breaker according to the electromagnetic field strength signal.

Here, the magneto-resistive element 141 detects an electromagnetic field strength signal according to a magneto-resistive effect. The magnetoresistance effect refers to a phenomenon that the resistance of some metal or semiconductor materials in a magnetic field increases along with the increase of the magnetic field, and like the hall effect, the magnetoresistance effect is also generated because carriers are subjected to lorentz force in the magnetic field. When the carrier reaches a steady state, the electric field force applied to the carriers at a certain speed is equal to the Lorentz force, the carriers are gathered at two ends to generate Hall electric fields, the carriers slower than the speed deflect towards the electric field force direction, and the carriers faster than the speed deflect towards the Lorentz force direction. This deflection leads to an increased drift path for the carriers. Alternatively, the number of carriers moving in the direction of the applied electric field decreases, thereby increasing the resistance, a phenomenon known as the magnetoresistance effect. The accuracy of the magnetoresistance effect measurement can reach 0.01%.

The pressure sensing module 15 includes a ceramic pressure sensor 151 and a pressure calculating unit 152, which are connected in sequence, wherein the ceramic pressure sensor 151 is used for detecting a pressure analog signal of the tulip contact spring, and the pressure calculating unit 152 is used for converting the pressure analog signal into a pressure value.

The temperature acquisition module 16 includes a temperature sensing element 161 and a temperature processing unit 162, which are connected in sequence, wherein the temperature sensing element 161 is used for detecting the temperature signal of the tulip contact, and the temperature processing unit 162 is used for converting the temperature signal into a temperature value.

Wherein, intelligence perception ring 1 installs on the plum blossom contact of circuit breaker.

The switch cabinet can be moved out along with the circuit breaker handcart during maintenance, and daily maintenance is facilitated.

The intelligent switch cabinet one-button sequential control system comprises the following working processes:

the infrared distance measuring module 13 monitors the insertion depth of the tulip contact, the load sensing module 14 monitors the current value flowing through the tulip contact, the pressure sensing module 15 monitors the pressure of the tulip contact, the temperature acquisition module 16 monitors the temperature of the tulip contact, and the system main control module 12 acquires the insertion depth, the flowing current value, the pressure and the temperature of the breaker tulip contact and transmits the insertion depth, the flowing current value, the pressure and the temperature to the intelligent assembly 2 through the wireless communication module 17; when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, the intelligent assembly 2 drives the handcart working position relay 21 to act, and a remote measurement criterion is provided for the one-key sequence control host 3; when the current value flowing through the tulip contact is larger than the current set value, the intelligent assembly 2 drives the breaker closing state relay 22 to act, and telemetering criteria are provided for the one-key sequence control host 3.

The one-key sequence control host 3 and the circuit breaker opening and closing confirmation 'position remote signaling criterion + remote measuring criterion': selecting a normally open signal of an auxiliary point in a closing state of the circuit breaker as a first criterion; the load sensing module 14 monitors the current value flowing through the tulip contact and drives the circuit breaker closing state relay 22 to drive an auxiliary contact normally open signal as a second criterion through the intelligent assembly 2. Confirming 'position remote signaling criterion + remote measuring criterion' of handcart working position: selecting a normally open signal of an auxiliary point of a working position of the circuit breaker as a first criterion; the infrared distance measuring module 13 monitors the insertion depth of the tulip contact and drives a handcart working position relay 21 auxiliary contact normally open signal through the intelligent assembly 2 to serve as a second criterion. The method adopts 'position remote signaling criterion + remote measuring criterion', and judges whether the equipment is operated in place or not by the corresponding change of the indication of two non-identical principles.

In conclusion, the intelligent switch cabinet one-button sequential control method adopts 'position remote signaling criterion + remote measuring criterion', and judges whether the equipment is operated in place or not by correspondingly changing the indications of two non-identical principles.

The intelligent switch cabinet one-button sequence control method provided by the invention is described in detail above. The principles and embodiments of the present invention are explained herein using specific examples, which are presented only to assist in understanding the present invention and its core concepts. It should be noted that, for those skilled in the art, it is possible to make various improvements and modifications to the present invention without departing from the principle of the present invention, and those improvements and modifications also fall within the scope of the claims of the present invention.

Claims (9)

1. A one-button sequential control method for an intelligent switch cabinet is characterized by comprising the following steps:

step S1, signal acquisition: acquiring the insertion depth, the flowing current value, the pressure and the temperature of a plum blossom contact of the circuit breaker;

step S2, signal comparison: comparing the insertion depth of the plum blossom-shaped contact of the circuit breaker with the set value of the depth, and comparing the value of the current flowing through the circuit breaker with the set value of the current;

step S3, drive telemetry: when the insertion depth of the plum blossom contact of the circuit breaker is greater than a depth set value, driving a remote measurement criterion of the working position of the handcart; when the current value flowing through the circuit breaker is larger than the current set value, driving a remote measurement criterion of the closing state of the circuit breaker;

step S4, judging in place: selecting a circuit breaker closing state auxiliary contact normally open signal as a position remote signaling criterion, and determining 'position remote signaling criterion + remote measurement criterion' when the circuit breaker is closed and opened; the method comprises the steps of selecting a circuit breaker handcart working position auxiliary contact normally open signal as a position remote signaling criterion, and confirming 'the position remote signaling criterion + a remote measuring criterion' on the handcart working position.

2. The one-touch sequence control method of the intelligent switch cabinet as claimed in claim 1, wherein the insertion depth of the breaker tulip contact in the step S1 is collected through an infrared ranging module (13), and the method specifically comprises the following steps:

a1, measuring the distance from the infrared distance measuring module (13) to the fixed contact copper bar;

and A2, calculating the insertion depth of the tulip contact according to the distance from the infrared distance measuring module (13) to the copper bar of the fixed contact, the external dimension of the fixed contact and the installation position of the intelligent sensing ring (1).

3. The intelligent switch cabinet one-button sequential control method according to claim 2, wherein the current value flowing through the circuit breaker is collected through a load sensing module (14), and the method specifically comprises the following steps:

b1, detecting an electromagnetic field intensity signal at the plum blossom contact of the circuit breaker;

and step B2, calculating the current value flowing through the breaker according to the electromagnetic field intensity signal.

4. The one-button sequential control method for the intelligent switch cabinet according to claim 3, wherein the pressure of the circuit breaker is collected through a pressure sensing module (15), and the method specifically comprises the following steps:

step C1, detecting a pressure analog signal of the plum blossom contact spring;

and step C2, converting the pressure analog signal into a pressure value.

5. The one-button sequential control method of the intelligent switch cabinet as claimed in claim 4, wherein the temperature of the breaker tulip contact is collected by a temperature collection module (16), and the method specifically comprises the following steps:

d1, detecting a temperature signal of the tulip contact;

and D2, converting the temperature signal into a temperature value.

6. The method according to claim 5, wherein the step S1 is implemented by using an intelligent sensing ring (1) for signal acquisition, the intelligent sensing ring (1) comprises an equipment power supply module (11), a system main control module (12), an infrared distance measuring module (13), a load sensing module (14), a pressure sensing module (15), a temperature acquisition module (16) and a wireless communication module (17), and the system main control module (12) is used for acquiring the insertion depth, the flowing current value, the pressure and the temperature of the plum blossom contact of the circuit breaker and transmitting the acquired values to the intelligent assembly (2) through the wireless communication module (17).

7. The intelligent switch cabinet one-button sequential control method according to claim 6, characterized in that the intelligent sensing ring (1) is installed on a plum blossom contact of a circuit breaker.

8. An intelligent switch cabinet one-button sequence control method according to claim 6 or 7, characterized in that, the steps S2 and S3 are carried out by the intelligent assembly (2) for signal comparison and drive remote measurement, and the intelligent assembly (2) transmits the hard contact signals of the on-off state of the circuit breaker and the working position of the circuit breaker handcart to the one-button sequence control host (3).

9. The intelligent switch cabinet one-button sequential control method according to claim 8, wherein the intelligent assembly (2) comprises a handcart working position relay (21), a breaker closing state relay (22), a comparison unit (23) and a driving unit (24), and when the comparison unit (23) judges that the insertion depth of the breaker tulip contact is greater than a depth set value, the driving unit (24) drives the handcart working position relay (21) to act; when the comparison unit (23) judges that the current value flowing through the circuit breaker is larger than the current set value, the driving unit (24) drives the circuit breaker closing state relay (22) to act.

Images