CN213934004U - Residual current detection device - Google Patents
Residual current detection device Download PDFInfo
- Publication number
- CN213934004U CN213934004U CN202023093842.6U CN202023093842U CN213934004U CN 213934004 U CN213934004 U CN 213934004U CN 202023093842 U CN202023093842 U CN 202023093842U CN 213934004 U CN213934004 U CN 213934004U
- Authority
- CN
- China
- Prior art keywords
- residual current
- current
- coil
- controller
- detection device
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Abstract
The utility model relates to a residual current detection device, which comprises a peridium coil, a primary circuit and a secondary circuit, wherein the peridium coil is used for collecting the residual current of the primary circuit and providing a detection signal for a controller; the intermediate connection cable is used for connecting the secondary side of the wrapped coil and the primary side of the secondary CT so as to realize signal transmission; secondary CT, wherein a miniature current transformer is adopted to realize signal conversion from 5A or 1A current to 0-3.53V; and the controller is used for converting the acquired analog signals into digital signals and carrying out signal calculation processing. The utility model has the advantages that one covering coil simultaneously passes through A, B, C, N four wires, only 2 wires are led out to detect residual current, and the on-site construction wiring is simplified; the discrimination of fault signals and normal signals is increased, the switching locking fixed value can be set to be very small, the discrimination of the system is increased, and the primary side grounding current can be detected by 100% when reaching more than 10mA through field application verification.
Description
Technical Field
The utility model belongs to the technical field of the residual current detection technique and specifically relates to a residual current detection device.
Background
With the rapid development of national economy and the improvement of the living standard of people, the demand of society on electric power is increasing day by day, and higher requirements on the reliability and the quality of power supply are provided. Due to the increasing load, the reactive power demand of the power grid also increases. And the flow of reactive power in the power grid can increase the power grid loss, reduce the utilization rate of power grid equipment and reduce the power supply quality of a power system. Therefore, the solution of the reactive compensation problem has great significance for reducing loss and saving energy. Among them, 380V distribution side centralized packet switching capacitor compensation application is the most common.
The electric equipment in the power supply area has the characteristics of multiple points and wide range, and the electric equipment of different types can generate the problems of three-phase imbalance, harmonic interference, interphase short circuit, ground fault and the like. Therefore, the low-voltage reactive compensation must increase the locking conditions such as fault locking, three-phase unbalanced locking, harmonic content exceeding locking and the like so as to ensure the personal safety and the equipment safety. However, the fault characteristics of the fault are different in different development stages, the indexes are different, and particularly, the single-phase ground fault with different ground impedances is more difficult to accurately detect and identify in the early stage of the fault development, so that a large accident potential exists with a fault switching capacitor. Therefore, a high-precision method for detecting a single-phase earth fault signal is urgently needed to lock the capacitor switching at the early stage of the fault and send an alarm signal.
The conventional residual current detection includes 4 links, which are a primary CT 5, a connection cable 6, a secondary CT7 and a controller. The primary CT 5 converts a large primary current into a current signal of a rated output 5A or 1A. The converted current signal is connected to a secondary CT7 of the controller through a connection cable 6, the length of which is generally about 3 to 5 meters. The secondary CT7 is responsible for converting the current of 5A or 1A into a weak current signal which can be directly sampled and calculated by the controller AD chip, such as +/-5V. The schematic block diagram of the whole system is shown in fig. 1.
Detection errors may be introduced in 4 links of conventional residual current detection:
error of primary CT 5: the accurate grades of the current transformers are generally 0.2, 0.5, 1.0, 0.2S, 0.5S, 5P, 10P and the like. The special current transformer with S requires high enough precision within the load range of 1% -120%; the precision within the range of 20% -120% of the load is generally required to be high enough within 0.2, 0.5 and the like, the error of measuring 4 load points is generally smaller than a specified range, the error comprises a specific difference and an angular difference, so that the accuracy in vector calculation is ensured, and the current transformers such as 5P, 10P and the like are generally used for protecting relay appliances, namely the composite error under the short-circuit current is required to be smaller than a certain value, the 5P is smaller than 5%, and the 10P is smaller than 10%. The current transformer specifies different accuracies, i.e. error accuracies in different current ranges, depending on the application. In short, there is an accuracy error in a specified measurement range, and the accuracy cannot be guaranteed if the signal is small.
The connection cable 6: the connecting cable 6 can be essentially equivalent to a certain impedance (R + jX), and the equivalent impedances of cables with different lengths are different at different frequencies, so that the influence on the error is mainly to increase the angular difference of each phase.
Secondary CT 7: secondary CT7 is similar to primary CT 5, except that it introduces both specific and angular differences outside the measurement range.
A controller: in the acquisition and calculation process of the controller, due to the limitation of AD digit, the problem of theoretical minimum resolution exists, the size and the phase of an analog signal are difficult to restore by 100%, and errors are also generated in the process of calculating the residual current by vector synthesis.
Therefore, as the links of detecting and calculating residual current are more, and error factors with different sizes exist in each link, small fault signals are difficult to accurately detect in the early stage of the single-phase earth fault, and effective fault characteristics cannot be extracted.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a reduce residual current detection device who detects link, reduction error.
In order to achieve the above purpose, the utility model adopts the following technical scheme: a residual current detection device comprising:
the included coil is used for collecting residual current of a primary circuit and providing a detection signal for the controller;
the intermediate connection cable is used for connecting the secondary side of the wrapped coil and the primary side of the secondary CT so as to realize signal transmission;
secondary CT, wherein a miniature current transformer is adopted to realize the signal conversion from 5A or 1A current to 0-3.53V, and the requirement of an AD sampling range is met;
and the controller is used for converting the acquired analog signals into digital signals and carrying out signal calculation processing, thereby realizing line state monitoring, normal switching of the capacitor and locking protection during faults.
The peripheric coils are square with the side length of 800mm, and are sleeved on A, B, C, N four wires.
According to the above technical scheme, the beneficial effects of the utility model are that: firstly, one covering coil simultaneously penetrates through A, B, C, N four wires, only 2 wires are led out to detect residual current, the number of cables is changed from 6 to 2, and the field construction wiring is simplified; secondly, the discrimination of fault signals and normal signals is increased, as the residual current is infinitely close to 0 and the switching locking fixed value can be set to be very small regardless of the load current and the load balance condition in a normal state, the discrimination of the system is increased, and the primary side grounding current can be detected by 100% when reaching more than 10mA through field application verification; and thirdly, the residual current detection is applied to capacitor switching locking for the first time, so that the safety of capacitor switching is improved.
Drawings
Fig. 1 is a schematic view of a conventional residual current detection device;
FIG. 2 is a schematic view of the apparatus of the present invention;
fig. 3 is a schematic diagram of the structure of the wrap coil in fig. 2.
Detailed Description
As shown in fig. 2, a residual current detection device includes:
the included coil 1 is used for collecting residual current of a primary circuit and providing a detection signal for the controller;
the intermediate connection cable 2 is used for connecting the secondary side of the peripherical coil 1 and the primary side of the secondary CT 3 so as to realize signal transmission;
and the controller is used for converting the acquired analog signals into digital signals and carrying out signal calculation processing, thereby realizing line state monitoring, normal switching of the capacitor and locking protection during faults.
The peripheric coil 1 is a square with the side length of 800mm, and the peripheric coil 1 is sleeved on A, B, C, N four wires.
When the circuit works, an externally input three-phase primary current signal is collected through the enveloping coil 1, the current signal collected by the enveloping coil 1 is transmitted to the secondary CT 3 through the middle connecting cable, the controller collects and calculates an output signal of the secondary CT 3, judges the current running state of the circuit, performs capacitor switching according to the circuit condition, and prevents the circuit fault from being expanded when the circuit fault locking control input occurs.
As shown in figure 3, the peripherical coil 1 is square (800 × 800mm), A, B, C three phases are arranged horizontally in the middle, the horizontal distances between the phases and the side phases from the peripherical coil 1 are both 200mm, and I is realizeda+Ib+Ic+INAnd (4) obtaining the residual current by vector synthesis.
To sum up, the utility model discloses a peridium coil 1 passes A, B, C, N four lines simultaneously, only draws out 2 lines and detects the residual current, and the cable quantity is changed into 2 from 6, has simplified the site operation wiring; the discrimination of fault signals and normal signals is increased, as the load current and the load balance condition are irrelevant under the normal state, the residual current is infinitely close to 0, the switching locking fixed value can be set to be very small, the discrimination of the system is increased, and the primary side grounding current can be detected by 100 percent when reaching more than 10mA through field application verification.
Claims (2)
1. A residual current detection device, its characterized in that: the method comprises the following steps:
the included coil is used for collecting residual current of a primary circuit and providing a detection signal for the controller;
the intermediate connection cable is used for connecting the secondary side of the wrapped coil and the primary side of the secondary CT so as to realize signal transmission;
secondary CT, wherein a miniature current transformer is adopted to realize the signal conversion from 5A or 1A current to 0-3.53V, and the requirement of an AD sampling range is met;
and the controller is used for converting the acquired analog signals into digital signals and carrying out signal calculation processing, thereby realizing line state monitoring, normal switching of the capacitor and locking protection during faults.
2. The residual current detection device according to claim 1, characterized in that: the peripheric coils are square with the side length of 800mm, and are sleeved on A, B, C, N four wires.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202023093842.6U CN213934004U (en) | 2020-12-21 | 2020-12-21 | Residual current detection device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN202023093842.6U CN213934004U (en) | 2020-12-21 | 2020-12-21 | Residual current detection device |
Publications (1)
Publication Number | Publication Date |
---|---|
CN213934004U true CN213934004U (en) | 2021-08-10 |
Family
ID=77153905
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN202023093842.6U Active CN213934004U (en) | 2020-12-21 | 2020-12-21 | Residual current detection device |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN213934004U (en) |
-
2020
- 2020-12-21 CN CN202023093842.6U patent/CN213934004U/en active Active
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CA2736574C (en) | Three-phase electric energy measurement apparatus | |
US9018938B2 (en) | Integrated device suspended at high voltage potential for power energy metering and protection of distribution network | |
CN103605015B (en) | High-precision electric parameter measurement dry-type reactor on-Line Monitor Device and method | |
CN101576601B (en) | Hidden failure diagnostic method of digital transformer protector measuring loop | |
RU2583452C2 (en) | Directed detection of resistive ground fault and rupture of conductor of medium voltage | |
CN102879716A (en) | Method and device for monitoring main insulation of three phases of cables under intersection and interconnection of metal protective layers on line | |
CN101320908B (en) | Interturn starting method of shunt reactor | |
CN110350483A (en) | Power converter plant and fault detection method with Earth Fault Detection function | |
CN102608499A (en) | Low-current line selection device and control method for inhibiting unbalanced current by way of differential filtration | |
CN110165778A (en) | A kind of oil-immersed power transformer non-ionizing energy loss fault wave recording device and method | |
CN107884645A (en) | Based on voltage ratio compared with power capacitor method for monitoring operation states | |
CN113075577A (en) | Residual current monitoring system and method for low-voltage alternating-current power supply system | |
CN111679163A (en) | On-line insulation monitoring device for turns of dry-type reactor | |
CN111610358B (en) | Method for calculating residual current by collecting three-phase and zero-sequence currents under three-phase four-wire system | |
CN213934004U (en) | Residual current detection device | |
CN101650379A (en) | Combined type sensor | |
CN112630519A (en) | Residual current detection device and method | |
JPH10248168A (en) | Preventive apparatus for single operation of dispersed power source | |
CN209841950U (en) | Depth fusion current sensor | |
CN102122140A (en) | Demarcation switch system | |
CN111337849A (en) | Novel leakage current measuring device and method | |
CN110609192A (en) | Low-voltage primary power system parameter acquisition system | |
CN104330447A (en) | System and method applied to on-line detection of capacitance of collective shunt capacitor | |
CN220626535U (en) | Reactive compensation device tester | |
CN202486266U (en) | Low-current line selecting device for inhibiting unbalanced current with differential filter |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
GR01 | Patent grant | ||
GR01 | Patent grant |