CN112362969A - Phase detection method - Google Patents

Abstract

The invention relates to a phase detection method, which comprises the following steps: storing the correspondingly demodulated signal received by the microprocessor in an internal memory and recording the phase corresponding to the signal; and (3) installing a signal generating end: the base is adsorbed on the equipment shell of the power supply end, and then the adjusting rod is adjusted to enable the magnet to be adsorbed beside the wiring terminal of the power supply end; then four insulation connecting clamps (7) are respectively clamped on the corresponding A-phase, B-phase, C-phase and D-phase wiring terminals; and (3) signal receiving end detection: an operator presses the control switch (102) to enable the probe (107) to extend out to contact with a terminal to be detected, the microprocessor displays phase information recognized by the microprocessor on the display screen (103) through the display driving module and gives an alarm prompt through the sound module. The invention provides a phase detection method which can quickly detect phases on the premise of not stopping power supply.

Description

Phase detection method

Technical Field

The invention relates to a phase detection method, and belongs to the field of power technology application.

Background

At present, in the process of power application, the phase of a terminal is often wrong due to maintenance, overhaul, user private wiring, and the like, so that a fault occurs when 220V voltage or 380V voltage needs to be accessed, and a fault easily occurs due to phase operation when high-end equipment with precise phase requirements is more serious. Therefore, the phase needs to be detected before the wiring of the equipment, and the conventional detection method is to separately connect a circuit at the power supply end and the power utilization end after the power is cut off until the circuits are matched and confirmed one by one, so that the whole process is time-consuming, labor-consuming and low in efficiency. Therefore, a detection method capable of solving the above problems is needed.

Disclosure of Invention

The present invention is directed to overcoming the above-mentioned disadvantages, and providing a phase detection method capable of performing phase detection rapidly without power outage.

The purpose of the invention is realized as follows:

a phase detection method comprises the following steps:

position correction: the probe is respectively connected with four insulating connecting clamps, each connection is kept for one minute, at the moment, the signal generating circuit sends out four different signals at intervals in one period, namely, one period is evenly divided into four stages, the four stages respectively send out four different signals, the four different signals are modulated by the carrier signal modulation circuit, meanwhile, the selection frequency of the switch selection circuit is consistent with the signal change frequency of the signal generating circuit, and the four different signals are respectively loaded on four different carrier signal coupling circuits, namely, at the moment, the four different signals are respectively loaded on the probe through the insulating connecting clamps after respectively passing through the four carrier signal coupling circuits after being selected by the switch selection circuit; the microprocessor receives the correspondingly demodulated signal and then stores the signal in an internal memory and records the phase corresponding to the signal;

and (3) installing a signal generating end: pressing the switch to enable the base to be adsorbed on the equipment shell of the power supply end, and then adjusting the adjusting rod to enable the magnet to be adsorbed beside the wiring terminal of the power supply end; then, after the four wires are respectively disassembled from the four reels, four insulating connecting clamps at the tail ends of the four wires are respectively clamped on the corresponding A-phase, B-phase, C-phase and D-phase wiring terminals;

and (3) signal receiving end detection: an operator presses the control switch to enable the probe to extend out to contact with a terminal to be tested, at the moment, after signals are input through the probe, the signals are demodulated through the carrier signal demodulation circuit and are identified by the microprocessor, the microprocessor displays phase information identified by the microprocessor on a display screen through the display driving module, and meanwhile, the microprocessor plays the phase information of the terminal through the voice module; then the operator controls the probe to contact another tested terminal until all the terminals are tested.

The invention relates to a phase detection method, wherein a signal wire between a probe and a signal receiving module is wound on a wire spool anticlockwise in the detection process of a signal receiving end, and when a gear rotates clockwise to extend the probe out of a phase, the wire spool synchronously rotates clockwise to lengthen the signal wire synchronously; when the gear rotates counterclockwise to retract the probe, the spool rotates counterclockwise in synchronization to wind the signal wire on the spool.

The invention relates to a phase detection method based on a phase detector, which comprises a signal generation module and a signal receiving module;

the signal generating module comprises a base, wherein an electromagnet and a storage battery are embedded in the base, and a switch is arranged on the base and is connected in series with a connecting power line between the electromagnet and the storage battery; the base is vertically and upwards provided with an installation column, a signal generation circuit is arranged in the installation column, the top of the installation column is connected with an adjusting rod through a joint bearing, and the top of the adjusting rod is connected with a magnetic part through the joint bearing;

the signal generating circuit comprises a signal generator, a carrier signal modulating circuit, a switch selecting circuit and a carrier signal coupling circuit, wherein the signal output end of the signal generator is connected with the input end of the carrier signal modulating circuit, the output end of the carrier signal modulating circuit is respectively connected with the input ends of the four carrier signal coupling circuits through the switch selecting circuit, and a lead connected with the output end of each carrier signal coupling circuit penetrates through the mounting column and then is respectively connected to the four insulating connecting clamps; the four connecting clamps are respectively marked with letters A, B, C and N;

the signal receiving module comprises a handle, a signal receiving circuit is arranged in the handle, a control switch and a display screen are installed on the outer wall of the handle, a transition cylinder is fixed at the end of the handle, a plurality of sliding rails are arranged in the transition cylinder along the length direction of the transition cylinder, a bearing is sleeved at the opening end of the transition cylinder, an insulating telescopic rod is inserted into the transition cylinder in a sliding mode through the bearing, a limiting ring is sleeved on the outer wall of the insulating telescopic rod in the transition cylinder in a sliding mode and is arranged on the sliding rails in a sliding mode, a rack is connected to the limiting ring or the insulating telescopic rod and is arranged on the sliding rails in a sliding mode, a gear is sleeved on a rotating shaft of a small motor installed in the transition cylinder in a sliding mode and is meshed with the rack, and a probe is inserted into the end of one end, located outside the;

the signal receiving circuit comprises a signal receiving module, a carrier signal demodulation circuit, a microprocessor, a display driving module and a voice module, wherein a probe is connected to the input end of the signal receiving module through a signal line, the output end of the signal receiving module inputs a signal into the carrier signal demodulation circuit and then the signal is demodulated and then input into the microprocessor, an IO port of the microprocessor is connected with the display driving module and the voice module, and the display driving module is connected with a display screen in a driving mode.

According to the phase detector, four reels are uniformly distributed on the periphery of the outer wall of the mounting column from top to bottom, and a lead between the output end of the carrier signal coupling circuit and the insulating connecting clamp is wound on the reels.

The invention relates to a phase detector, wherein a plurality of adjusting rods are arranged, and adjacent adjusting rods are hinged through joint bearings.

The invention relates to a phase detector, wherein a hook is arranged on an adjusting rod, the hook comprises a connecting piece, one end of the connecting piece is fixed on the adjusting rod, and a wire hanging ring with a notch is fixed at the other end of the connecting piece.

The invention relates to a phase detector.A power supply management module is installed in a mounting column, and a storage battery in a base supplies power for a signal generating circuit after passing through the power supply management module.

The invention relates to a phase detector, wherein a switch is connected in series with a connecting power line between a storage battery and a signal generating circuit.

The invention relates to a phase detector, wherein a wire spool is arranged on a rotating shaft of a small motor, and a signal wire between a probe and a signal receiving module is wound on the wire spool.

The invention relates to a phase detector, wherein a screw hole is formed in the center of an insulating telescopic rod along the length direction of the insulating telescopic rod, an external thread is arranged on the outer wall of one end of a probe, the probe is screwed in the screw hole of the insulating telescopic rod, one end of a signal connector is inserted into the screw hole and then welded to the bottom of the probe, and the other end of the signal wire penetrates through a transition cylinder and the shell wall of a handle and then is connected with a signal receiving module.

Compared with the prior art, the invention has the beneficial effects that:

the invention loads corresponding signals of different phases on lines of different phases by using a power carrier technology, thereby being convenient for quick detection, convenient and efficient to use, and simultaneously ensuring the continuity of power supply without power failure in the whole detection process. In addition, the conventional power failure detection mode can be carried out only after cooperation of multiple persons or even linkage control coordination of multiple departments, the method can be completed through single action on the basis of no power failure, the supporting component is installed at the power supply end, and the probe component can be used for paying off for detection when going to the power utilization end after the connection is completed.

Drawings

Fig. 1 is a schematic structural diagram of a supporting assembly of a phase detector according to the present invention.

Fig. 2 is a circuit block diagram of a signal generating circuit of a phase detector according to the present invention.

FIG. 3 is a schematic diagram of a probe assembly of the phase detector according to the present invention.

Fig. 4 is a circuit block diagram of a signal receiving circuit of a phase detector according to the present invention.

Wherein:

the device comprises a base 1, a mounting column 2, an adjusting rod 3, a joint bearing 4, a magnetic part 5, a hook 6 and an insulating connecting clamp 7;

a switch 1.1;

a reel 2.1;

a connecting piece 6.1 and a wire hanging ring 6.2;

the device comprises a handle 101, a control switch 102, a display screen 103, a transition cylinder 104, a slide rail 105, an insulating telescopic rod 106, a probe 107, a limit ring 108, a rack 109, a gear 110, a small motor 111 and a wire spool 112.

Detailed Description

Referring to fig. 1 to 4, the phase detector according to the present invention includes a signal generating module and a signal receiving module;

referring to fig. 1 and 2, the signal generating module includes a base 1, an electromagnet and a storage battery are embedded in the base 1, a switch 1.1 is arranged on the base 1, and the switch 1.1 is connected in series with a connecting power line between the electromagnet and the storage battery; the base 1 is vertically and upwards provided with an installation column 2, a signal generating circuit is arranged in the installation column 2, the top of the installation column 2 is connected with an adjusting rod 3 through a joint bearing 4, and the top of the adjusting rod 3 is connected with a magnetic part 5 through the joint bearing 4;

the signal generating circuit comprises a signal generator, a carrier signal modulating circuit, a switch selecting circuit and a carrier signal coupling circuit, wherein the signal output end of the signal generator is connected with the input end of the carrier signal modulating circuit, the output end of the carrier signal modulating circuit is respectively connected with the input ends of the four carrier signal coupling circuits through the switch selecting circuit, and a lead connected with the output end of each carrier signal coupling circuit penetrates through the mounting column 2 and then is respectively connected to the four insulating connecting clamps 7; and the four connecting clips 7 are respectively marked with letters A, B, C and N;

preferably, four reels 2.1 are uniformly distributed on the periphery of the outer wall of the mounting column 2 from top to bottom, and a lead between the output end of the carrier signal coupling circuit and the insulating connecting clamp 7 is wound on the reels 2.1, so that the storage is convenient;

preferably, a plurality of adjusting rods 3 are arranged, and adjacent adjusting rods 3 are hinged through joint bearings 4;

preferably, the adjusting rod 3 is provided with a hook 6, the hook 6 comprises a connecting piece 6.1, one end of the connecting piece 6.1 is fixed on the adjusting rod 3, and the other end is fixed with a wire hanging ring 6.2 with a notch, so that a wire can be conveniently clamped in the wire hanging ring 6.2 through the notch during use, and the wire is prevented from falling or being rubbed with internal electric devices;

preferably, a power management module is installed in the mounting column 2, and a storage battery in the base 1 supplies power to the signal generating circuit after passing through the power management module;

preferably, the switch 1.1 is connected in series with a connecting power line between the storage battery and the signal generating circuit, so that the signal generating circuit synchronously works while the switch 1.1 presses the electromagnet to work, and the signal generating circuit synchronously stops working when the electromagnet is closed, thereby realizing synchronization between the two;

referring to fig. 3 and 4, the signal receiving module includes a handle 101, a signal receiving circuit is disposed in the handle 101, the outer wall of the handle 101 is provided with a control switch 102 and a display screen 103, the end of the handle 101 is fixed with a transition cylinder 104, the transition cylinder 104 is internally provided with a plurality of slide rails 105 along the length direction thereof, the open end of the transition cylinder 104 is sleeved with a bearing, an insulating telescopic rod 106 is inserted into the transition cylinder 104 in a sliding way through the bearing, the outer wall of the insulating telescopic rod 106 positioned in the transition cylinder 104 is sleeved with a limit ring 108, and the limit ring 108 is slidably disposed on the slide rail 105, the rack 109 is connected to the limit ring 108 or the insulating telescopic rod 106, the rack 109 is slidably disposed on the slide rail 105, a gear 110 is sleeved on a rotating shaft of a small motor 111 installed in the transition cylinder 104, the gear 110 is engaged with the rack 109, and the probe 107 is inserted into the end of the insulating telescopic rod 106 at one end outside the transition cylinder 104;

the signal receiving circuit comprises a signal receiving module, a carrier signal demodulation circuit, a microprocessor, a display driving module and a voice module, wherein a probe 107 is connected to the input end of the signal receiving module through a signal line, the output end of the signal receiving module inputs a signal into the carrier signal demodulation circuit for demodulation and then inputs the signal into the microprocessor, an IO port of the microprocessor is connected with the display driving module and the voice module, and the display driving module is connected with the display screen 103 in a driving way;

preferably, a wire spool 112 is provided on the rotation shaft of the small motor 111, and the signal line between the probe 107 and the signal receiving module is wound on the wire spool 112;

preferably, a screw hole is formed in the center of the insulating telescopic rod 106 along the length direction of the insulating telescopic rod, an external thread is formed on the outer wall of one end of the probe 107, the probe 107 is screwed into the screw hole of the insulating telescopic rod 106, one end of the signal connector is inserted into the screw hole and then welded to the bottom of the probe 107, and the other end of the signal wire penetrates through the wall of the transition cylinder 104 and the wall of the handle 101 and then is connected with the signal receiving module;

a phase detection method comprises the following steps:

position correction: the probe 107 is respectively connected with four insulating connecting clamps 7, each connection is kept for one minute, at the moment, the signal generating circuit sends out four different signals at intervals in one period, namely, one period is evenly divided into four stages, the four stages respectively send out four different signals, the four different signals are modulated by the carrier signal modulation circuit, meanwhile, the selection frequency of the switch selection circuit is kept consistent with the signal change frequency of the signal generating circuit, and the four different signals are respectively loaded on four different carrier signal coupling circuits, namely, the four different signals are respectively loaded on the probe 107 through the insulating connecting clamps 7 after being selected by the switch selection circuit and then respectively passing through the four carrier signal coupling circuits; the microprocessor receives the correspondingly demodulated signal and then stores the signal in an internal memory and records the phase corresponding to the signal;

can be convenient one set of signal generator and carrier signal modulation circuit of sharing through switch selection circuit, in the occasion that the required precision is not high or the stable occasion of circuit quality, one set of switch selection circuit of carrier signal coupling circuit and switch selection circuit's position can be exchanged sharing, adopts this patent scheme in the great occasion of disturbing, through different coupling parameter selection, can optimize carrier signal and be convenient for detect discernment and do not disturb, the precision is higher.

And (3) installing a signal generating end: pressing the switch 1.1 to enable the base to be adsorbed on the equipment shell of the power supply end, and then adjusting the adjusting rod 3 to enable the magnet 5 to be adsorbed beside the wiring terminal of the power supply end; then, after the four wires are respectively disassembled from the four reels 2.1, four insulating connecting clamps 7 at the tail ends of the four wires are respectively clamped on the corresponding A-phase, B-phase, C-phase and D-phase wiring terminals;

and (3) signal receiving end detection: an operator presses the control switch 102 to enable the probe 107 to extend out to contact with a terminal to be tested, at the moment, after signals are input through the probe 107, the signals are demodulated through the carrier signal demodulation circuit and are identified by the microprocessor, the microprocessor displays phase information identified by the microprocessor on the display screen 103 through the display driving module, and meanwhile, the microprocessor plays the phase information of the terminal through the voice module; then the operator controls the probe 107 to contact another tested terminal until all the terminals are tested;

meanwhile, in the process of signal receiving end detection, a signal wire between the probe 107 and the signal receiving module is wound on the wire spool 112 anticlockwise, and when the gear 110 rotates clockwise to stretch the probe 107 out of the phase, the wire spool 112 rotates clockwise synchronously to lengthen the signal wire synchronously; when the gear 110 rotates counterclockwise to retract the probe 107, the wire spool 112 rotates counterclockwise in synchronization to wind the signal wire on the wire spool 112; thereby preventing the signal wires in the internal process from knotting;

in addition: it should be noted that the above-mentioned embodiment is only a preferred embodiment of the present patent, and any modification or improvement made by those skilled in the art based on the above-mentioned conception is within the protection scope of the present patent.

Claims (6)

1. A phase detection method, characterized by: the detection method comprises the following steps:

position correction: the probe (107) is respectively connected with four insulating connecting clamps (7), each connection is kept for one minute, at the moment, the signal generating circuit sends out four different signals at intervals in one period, namely, one period is evenly divided into four stages, the four stages respectively send out four different signals which are modulated by the carrier signal modulation circuit, meanwhile, the selection frequency of the switch selection circuit is kept consistent with the signal change frequency of the signal generating circuit, and the four different signals are respectively loaded on four different carrier signal coupling circuits, namely, at the moment, the four different signals are respectively loaded on the probe (107) through the insulating connecting clamps (7) after respectively passing through the four carrier signal coupling circuits after being selected by the switch selection circuit; the microprocessor receives the correspondingly demodulated signal and then stores the signal in an internal memory and records the phase corresponding to the signal;

and (3) installing a signal generating end: pressing a switch (1.1) to enable the base to be adsorbed on the equipment shell of the power supply end, and then adjusting an adjusting rod (3) to enable a magnet (5) to be adsorbed beside a wiring terminal of the power supply end; then, after four wires are respectively disassembled from the four reels (2.1), four insulating connecting clamps (7) at the tail ends of the four wires are respectively clamped on the corresponding A-phase, B-phase, C-phase and D-phase wiring terminals;

and (3) signal receiving end detection: an operator presses the control switch (102) to enable the probe (107) to extend out to contact with a terminal to be tested, at the moment, after signals are input through the probe (107), the signals are demodulated through the carrier signal demodulation circuit and are identified by the microprocessor, the microprocessor displays phase information identified by the microprocessor on the display screen (103) through the display driving module, and meanwhile, the microprocessor plays the phase information of the terminal through the voice module; then the operator controls the probe (107) to contact another tested terminal until all the terminals are tested;

the detection method is based on a phase detector, and the phase detector comprises a signal generation module and a signal receiving module;

the signal generation module comprises a base (1), an electromagnet and a storage battery are embedded in the base (1), a switch (1.1) is arranged on the base (1), and the switch (1.1) is connected in series with a connecting power line between the electromagnet and the storage battery; a mounting column (2) is vertically and upwardly mounted on the base (1), a signal generating circuit is arranged in the mounting column (2), the top of the mounting column (2) is connected with an adjusting rod (3) through a joint bearing (4), and the top of the adjusting rod (3) is connected with a magnetic part (5) through the joint bearing (4);

the signal generating circuit comprises a signal generator, a carrier signal modulating circuit, a switch selecting circuit and a carrier signal coupling circuit, wherein the signal output end of the signal generator is connected with the input end of the carrier signal modulating circuit, the output end of the carrier signal modulating circuit is respectively connected with the input ends of the four carrier signal coupling circuits through the switch selecting circuit, and a lead connected with the output end of each carrier signal coupling circuit penetrates through the mounting column (2) and then is respectively connected to the four insulating connecting clamps (7); the four connecting clamps (7) are respectively marked with letters A, B, C and N;

four reels (2.1) are uniformly distributed on the periphery of the outer wall of the mounting column (2) from top to bottom, and a lead between the output end of the carrier signal coupling circuit and the insulating connecting clamp (7) is wound on the reels (2.1);

the signal receiving module comprises a handle (101), a signal receiving circuit is arranged in the handle (101), a control switch (102) and a display screen (103) are installed on the outer wall of the handle (101), a transition cylinder (104) is fixed at the end of the handle (101), a plurality of sliding rails (105) are arranged in the transition cylinder (104) along the length direction of the transition cylinder, a bearing is sleeved at the opening end of the transition cylinder (104), an insulating telescopic rod (106) is slidably inserted into the transition cylinder (104) through the bearing, a limiting ring (108) is sleeved on the outer wall of the insulating telescopic rod (106) in the transition cylinder (104), the limiting ring (108) is slidably arranged on the sliding rails (105), a rack (109) is connected to the limiting ring (108) or the insulating telescopic rod (106), the rack (109) is slidably arranged on the sliding rails (105), a gear (110) is sleeved on a rotating shaft of a small motor (111) installed in the transition cylinder (104), the gear (110) is meshed with the rack (109), and the probe (107) is inserted into the end part of one end of the insulating telescopic rod (106) outside the transition cylinder (104);

the signal receiving circuit comprises a signal receiving module, a carrier signal demodulation circuit, a microprocessor, a display driving module and a voice module, wherein a probe (107) is connected to the input end of the signal receiving module through a signal line, the output end of the signal receiving module inputs a signal into the carrier signal demodulation circuit and then the signal is demodulated and then input into the microprocessor, an IO port of the microprocessor is connected with the display driving module and the voice module, and the display driving module is connected with a display screen (103) in a driving mode.

2. A phase detection method as claimed in claim 1, characterized in that: a wire spool (112) is arranged on a rotating shaft of the small motor (111), and a signal wire between the probe (107) and the signal receiving module is wound on the wire spool (112); a screw hole is formed in the center of the insulating telescopic rod (106) along the length direction of the insulating telescopic rod, an external thread is formed in the outer wall of one end of the probe (107), the probe (107) is arranged in the screw hole of the insulating telescopic rod (106) in a rotating mode, one end of a signal connector is inserted into the screw hole and then welded to the bottom of the probe (107), and the other end of the signal wire penetrates through the wall of the transition cylinder (104) and the wall of the handle (101) and then is connected with the signal receiving module; in the process of detecting a signal receiving end, a signal wire between the probe (107) and the signal receiving module is wound on the wire spool (112) anticlockwise, and when the gear (110) rotates clockwise to stretch the probe (107) out of the phase, the wire spool (112) synchronously rotates clockwise to synchronously lengthen the signal wire; when the gear (110) rotates counterclockwise to retract the probe (107), the spool (112) rotates counterclockwise in synchronization to wind the signal wire on the spool (112).

3. A phase detection method as claimed in claim 1, characterized in that: the adjusting rods (3) are provided with a plurality of adjusting rods, and the adjacent adjusting rods (3) are hinged through joint bearings (4).

4. A phase detection method as claimed in claim 1, characterized in that: the adjusting rod (3) is provided with a hook (6), the hook (6) comprises a connecting piece (6.1), one end of the connecting piece (6.1) is fixed on the adjusting rod (3), and the other end is fixedly provided with a hanging wire ring (6.2) with an opening.

5. A phase detection method as claimed in claim 1, characterized in that: a power supply management module is installed in the mounting column (2), and a storage battery in the base (1) supplies power for the signal generation circuit after passing through the power supply management module.

6. A phase detection method as claimed in claim 1, characterized in that: the switch (1.1) is connected in series with a connecting power line between the storage battery and the signal generating circuit.

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