CN117214481B - Distributed power access-based detection equipment for power control of power grid - Google Patents

Abstract

The invention discloses detection equipment for power control of a power grid based on distributed power supply access, which belongs to the technical field of power control devices, wherein a power detection module is electrically connected with a processor, the processor is electrically connected with a power control module, the power control module is electrically connected with a display module, a middle wiring is fixedly arranged at the middle part of one end of an inner cavity of a shell, the middle wiring penetrates through the bottom of a power detection sensor and is electrically connected with the middle wiring, compression sleeves are respectively arranged at two sides of one end of the inner cavity of the shell and are respectively sleeved at two ends of the middle wiring, and a protective sleeve is embedded at the other end of the inner cavity of the shell.

Description

Distributed power access-based detection equipment for power control of power grid

Technical Field

The invention relates to the technical field of power control devices, in particular to a detection device for power control of a power grid based on distributed power supply access.

Background

In the smart grid construction process, smart micro-grids are of paramount importance in development. One of the key technologies of the smart micro-grid is stable balance control of power under the constraint condition of grid stability, and the real-time performance of the control is a key in the key. In order to ensure the development of coordination and cooperation between the power grid and the power sources, the intelligent power grid is generally connected with a plurality of power sources in a distributed mode, and the electric power of each power source connected with the electric wire is generally required to be detected by using detection equipment, so that the coordination and cooperation effect between the power grid and the power sources is regulated and controlled.

The detection equipment for power control of the current electric wire netting is when using, usually needs to install detection module in the circuit electric wire to realize the real-time detection to the power, but detection equipment is all in an organic whole setting usually, after connecting the positive negative pole to the circuit in, not only can let the circuit internal line of detection expose outside, damages easily and takes place the incident, and detection equipment is difficult to directly install on the circuit and dismantle simultaneously, and the installation dismantlement degree of difficulty is big, and stability is poor, inconvenient change maintenance.

Aiming at the problems, the detection equipment for controlling the power of the power grid based on distributed power supply access is provided.

Disclosure of Invention

The invention aims to provide a detection device for power control of a power grid based on distributed power supply access, which adopts the device to work, so that the problems that the detection device is generally arranged in an integrated mode in the background, after a positive electrode and a negative electrode are connected to a circuit, the detected circuit internal line is exposed, the damage and safety accidents are easy to occur, meanwhile, the detection device is difficult to directly install and detach on the circuit, the installation and detachment difficulty is high, the stability is poor, and the replacement and the maintenance are inconvenient are solved.

In order to achieve the above purpose, the present invention provides the following technical solutions: the power detection module is used for monitoring the electric power on an access electric wire in real time, the power detection module is electrically connected with the processor, the processor is electrically connected with the power control module, the processor is used for processing monitoring data sent by the power detection module and controlling the power control module to control and adjust the electric power of a circuit, the power control module is electrically connected with the display module, and the display module is used for intensively displaying the real-time data of the electric power;

the power detection module comprises a shell and a power detection sensor fixedly installed at the middle part of one end of the inner cavity of the shell, a middle wiring is fixedly installed at the middle part of one end of the inner cavity of the shell, the middle wiring penetrates through the bottom of the power detection sensor, the power detection sensor is electrically connected with the middle wiring, a pressing sleeve is installed at two sides of one end of the inner cavity of the shell respectively, the pressing sleeves are sleeved at two ends of the middle wiring respectively, and a protective sleeve is installed at the other end of the inner cavity of the shell in an embedded mode.

Further, the embedded groove is formed in the shell, the side wall sliding holes are formed in the outer walls of the two sides of the shell respectively, the embedded groove is communicated with the side wall sliding holes, a first inner embedded groove and a second inner embedded groove are symmetrically formed in the inner cavity of the embedded groove and located on the two sides of the power detection sensor, and the second inner embedded groove is located between the side wall sliding holes and the first inner embedded groove.

Further, a receiving groove is formed in the bottom surface of the inner cavity of the embedding groove, and a semicircular clamping block is elastically and slidably arranged at the opening of the inner cavity of the receiving groove through a reset spring.

Further, the middle wiring comprises a hard metal wiring and pushing sleeves respectively fixedly sleeved on the outer walls of two end parts of the hard metal wiring, protruding blocks are respectively fixedly installed on the outer walls of the pushing sleeves, inserting pushing blocks are fixedly installed on the outer walls of the protruding blocks, and pushing sliding shafts are respectively fixedly installed on the outer walls of the inserting pushing blocks.

Further, the compressing sleeve comprises a round outer sleeve and compressing sliding blocks which are slidably arranged at the upper end and the lower end of the front end of the inner cavity of the round outer sleeve, and the inner end of the round outer sleeve is slidably sleeved on the pushing sleeve.

Further, the middle part department of circular overcoat is provided with T type round hole, and is provided with the interior spout of elasticity on the top surface and the bottom surface of T type round hole inner chamber respectively, and installs extension spring on the interior inslot of elasticity, is provided with the interior spout of restriction on the top surface and the bottom surface of T type round hole inner chamber respectively, and is linked together through the well smooth hole between spout in the restriction and the elasticity.

Further, the protruding block slides and sets up in the interior spout of elasticity, and extension spring's one end connection installs on the outer wall of protruding block, compresses tightly the slider and slides respectively and set up in the restriction interior spout.

Further, the inner cavity of the pressing sliding block is provided with a pushing groove, the inner walls of the two sides of the inner cavity of the pushing groove are respectively provided with an inclined sliding groove, and the pushing sliding shafts are respectively arranged in the inclined sliding grooves in a sliding manner.

Further, the inner side of the protective sleeve is provided with a protective groove, two-way embedded holes are respectively formed in the outer walls of the two ends of the protective sleeve, the protective groove is respectively communicated with the two-way embedded holes, and a semicircular clamping groove is formed in the bottom surface of the protective sleeve.

Further, the semicircular clamping blocks are movably clamped in the semicircular clamping grooves respectively.

Compared with the prior art, the invention has the following beneficial effects: when the worker needs to take down the maintenance and change with the power detection sensor, then can pinch the shell with the finger and then pull the shell to one side, well wiring, compress tightly cover and electric wire netting wiring and then can slide to the opposite side with the shell respectively, can take down the shell from the follow wiring, compress tightly cover and electric wire netting wiring on, drive the protective sheath and cup joint in the outside of well wiring, compress tightly cover and electric wire netting wiring, finally under the effect of operator's tensile force, can realize taking down the power detection sensor, when installing once more, the reverse repeat above-mentioned step can, the structure sets up ingenious, the multiple effect can be accomplished simultaneously to an action, not only made things convenient for the installation dismantlement of power detection sensor, the protection to exposing the wire has also been realized simultaneously, prevent the wire damage, the emergence of electric shock accident has been avoided.

Drawings

FIG. 1 is a grid power control flow chart of the present invention;

FIG. 2 is a schematic diagram of a power detection module according to the present invention;

FIG. 3 is a schematic top view of the housing of the present invention;

FIG. 4 is a schematic perspective view of a housing according to the present invention;

FIG. 5 is a schematic diagram of the medium and grid connection state of the present invention;

FIG. 6 is a schematic diagram of the split state of the medium and grid connections of the present invention;

FIG. 7 is a schematic view of a mid-junction planar structure of the present invention;

FIG. 8 is a schematic cross-sectional view of a circular outer sleeve of the present invention;

FIG. 9 is a schematic perspective view of a pressing slider of the present invention;

fig. 10 is a schematic perspective view of a protective sleeve according to the present invention.

In the figure: 1. a power detection module; 11. a housing; 111. embedding the groove; 1111. a receiving groove; 1112. a semicircular clamping block; 1113. a return spring; 112. a side wall slide hole; 113. a first internal embedded groove; 114. a second internal insertion groove; 12. a power detection sensor; 13. a medium wiring; 131. a hard metal wiring; 132. pushing the sleeve; 133. a protruding block; 134. inserting a pushing block; 135. pushing the slide shaft; 14. a compacting sleeve; 141. a circular outer jacket; 1411. a T-shaped round hole; 1412. an elastic inner chute; 1413. a tension spring; 1414. limiting the inner chute; 1415. a middle slide hole; 142. a pressing slide block; 1421. pushing the groove; 1422. tilting the chute; 15. a protective sleeve; 151. a protection groove; 152. a semicircular clamping groove; 153. a double-pass embedded hole; 16. connecting a power grid; 2. a processor; 3. a power control module; 4. and a display module.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In order to solve the technical problems that detection equipment is generally arranged in an integrated manner, after positive and negative electrodes are connected to a circuit, the detected circuit inner line is exposed, the detection equipment is easy to damage and safety accidents, meanwhile, the detection equipment is difficult to directly mount and dismount on the circuit, the mounting and dismounting difficulty is high, the stability is poor, and replacement and maintenance are inconvenient, as shown in fig. 1-6 and 10, the following preferable technical scheme is provided:

the utility model provides a power grid power control is with check out test set based on distributed power access, including power detection module 1, including power detection module A in the power detection module 1, power detection module B, power detection module C etc. power detection module is provided with a plurality ofly, install respectively and set up on the electric wire netting wire 16 of power access electric wire, power detection module 1 is used for the real-time supervision to insert electric power on the electric wire, electric connection between power detection module 1 and the treater 2, electric connection between treater 2 and the power control module 3, including power control module A in the power control module 3, power control module B and power control module C etc. install respectively and set up on the electric wire netting wire 16 of power access electric wire, treater 2 is used for handling the monitor data that power detection module 1 sent, and control power control module 3 controls the adjustment to circuit electric power, electric connection between power control module 3 and the display module 4, display module 4 then is used for concentrating the real-time data of display electric power, make things convenient for the staff to observe.

The power detection module 1 comprises a shell 11 and a power detection sensor 12 fixedly installed at the middle part of one end of the inner cavity of the shell 11, a middle wiring 13 is fixedly installed at the middle part of one end of the inner cavity of the shell 11, the middle wiring 13 penetrates through the bottom part of the power detection sensor 12, the power detection sensor 12 is electrically connected with the middle wiring 13, a pressing sleeve 14 is installed at two sides of one end of the inner cavity of the shell 11 respectively, the pressing sleeve 14 is sleeved at two ends of the middle wiring 13 respectively, a protective sleeve 15 is installed at the other end of the inner cavity of the shell 11 in an embedded manner, a power grid wiring 16 is installed in the pressing sleeve 14 in a connected manner, the power grid wiring 16 is electrically connected with the middle wiring 13, an embedded groove 111 is formed in the shell 11, side wall sliding holes 112 are formed in the outer walls of two sides of the shell 11 respectively, the embedded groove 111 are communicated with the side wall sliding holes 112, a first inner embedded groove 113 and a second inner embedded groove 114 are symmetrically formed in the inner cavity of the power detection sensor 12, the second inner embedded groove 114 is located between the side wall sliding holes 112 and the first inner embedded groove 113, the pressing sleeve 14 is slidably arranged at the bottom surface of the inner cavity 111, a reset spring 1111 is slidably arranged at the inner wall 1111 of the inner cavity 111, and the inner wall of the reset groove 111 is fixedly embedded in the inner cavity 111 is formed in the inner cavity 111, and the bottom of the reset groove is formed by the inner cavity 111, and the reset groove is formed in the cavity 111, and the cavity is arranged at the cavity 1111, and is formed by the cavity and is arranged at the cavity inside the cavity and is formed by the cavity and is formed by the cavity.

The inboard of protective sheath 15 is provided with protection groove 151, and is provided with the bi-pass on the both ends outer wall of protective sheath 15 respectively and inlays the hole 153, and protection groove 151 is linked together respectively with bi-pass between inlaying the hole 153, the bottom surface of protective sheath 15 is provided with semicircle draw-in groove 152, the inner chamber height of bi-pass inlaying the hole 153 and the diameter phase-match of electric wire netting wiring 16, semicircle fixture block 1112 activity joint respectively in semicircle draw-in groove 152, the both ends inner wall setting in protection groove 151 inner chamber is parallel and level with the outer end inner wall of second interior embedded groove 114 inner chamber.

Specifically, firstly, the power grid wiring 16 is cut off from the middle part, the cut ends of the power grid wiring 16 are respectively connected and installed at the two ends of the middle wiring 13 through the pressing sleeve 14, so that the power grid wiring 16 is respectively electrically connected with the middle wiring 13, when a worker needs to take down the power detection sensor 12 for maintenance and replacement, the worker can pinch the shell 11 with fingers and pull the shell 11 to one side, the middle wiring 13, the pressing sleeve 14 and the power grid wiring 16 slide towards the other side relative to the shell 11 respectively, at the moment, under the clamping limiting effect between the semicircular clamping blocks 1112 and the semicircular clamping grooves 152, the shell 11 can be taken down from the middle wiring 13, the pressing sleeve 14 and the power grid wiring 16, and simultaneously, the protective sleeve 15 is driven to be sleeved outside the middle wiring 13, the pressing sleeve 14 and the power grid wiring 16, finally, under the action of the operator tension force, the semicircular clamping blocks can be moved out of the semicircular clamping grooves 152, the power detection sensor 12 can be taken down, and when the power detection sensor is installed again, the steps are reversely repeated, the structure is arranged skillfully, multiple effects can be simultaneously completed by the operator, the power detection sensor 12 is convenient to be installed, and meanwhile, the electric shock accidents are prevented from being caused.

In order to solve the technical problem of how to quickly realize the installation and the disassembly between the power grid connection 16 and the middle connection 13, thereby facilitating the overall installation and the disassembly of the detection device, as shown in fig. 5-9, the following preferred technical scheme is provided:

the middle wiring 13 comprises a hard metal wiring 131 and pushing sleeves 132 respectively fixedly sleeved on the outer walls of two end parts of the hard metal wiring 131, protruding blocks 133 are respectively fixedly installed on the outer walls of the pushing sleeves 132, inserting pushing blocks 134 are fixedly installed on the outer walls of the protruding blocks 133, and pushing sliding shafts 135 are respectively fixedly installed on the outer walls of the inserting pushing blocks 134.

The compressing sleeve 14 comprises a round outer sleeve 141 and compressing sliding blocks 142 which are slidably mounted at the upper end and the lower end of the front end of the inner cavity of the round outer sleeve 141, the inner end of the round outer sleeve 141 is slidably sleeved on the pushing sleeve 132, T-shaped round holes 1411 are formed in the middle of the round outer sleeve 141, elastic inner sliding grooves 1412 are formed in the top surface and the bottom surface of the inner cavity of the T-shaped round holes 1411 respectively, extension springs 1413 are mounted on the inner cavity of the elastic inner sliding grooves 1412, limiting inner sliding grooves 1414 are formed in the top surface and the bottom surface of the inner cavity of the T-shaped round holes 1411 respectively, the limiting inner sliding grooves 1414 are communicated with the elastic inner sliding grooves 1412 through middle sliding holes 1415, the protruding blocks 133 are slidably arranged in the elastic inner sliding grooves 1412, one end portions of the extension springs 1413 are connected and mounted on the outer walls of the protruding blocks 133, the compressing sliding blocks 142 are slidably arranged in the limiting inner sliding grooves 1414 respectively, pushing grooves 1421 are formed in the inner cavities of the compressing sliding blocks 142, inclined sliding grooves 1422 are formed in the inner side walls of the inner cavities of the pushing grooves 1421 respectively, and the pushing shafts 135 are slidably arranged in the inclined sliding grooves 1422 respectively.

Specifically, when the detection device is required to be installed on the power grid wiring 16, the middle part of the power grid wiring 16 can be cut off, the inner ends of the cut ends of the power grid wiring 16 are respectively inserted into the pressing sleeves 14, the power grid wiring 16 is electrically connected with each other through the middle wiring 13, the pressing sleeves 14 can be respectively pushed inwards to slide inwards relative to the pushing sleeves 132, the front end parts of the pushing blocks 134 are inserted into the inner cavities of the elastic inner sliding grooves 1412, the whole pressing sliding blocks 142 can be driven to move towards the power grid wiring 16 under the limiting action of pushing the sliding shafts 135 and the inclined sliding grooves 1422, the cut ends of the power grid wiring 16 can be pressed and fixed, then the pressing sleeves 14 are respectively pressed into the protective sleeves 15, the whole shell 11 is sleeved on the protective sleeves 15, the pressing sleeves 14 are pushed into the second inner embedded grooves 114, the installation of the detection device can be realized, the shell 11 and the protective sleeves 15 can be directly removed during the disassembly, the disassembly is convenient and quick, the power detection device 12 can be disassembled, the power supply device can not be influenced, the power supply range of the power grid wiring 16 can be conveniently and widely used, and the power grid wiring 16 can be conveniently installed.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a power grid power control is with check out test set based on distributed power access, includes power detection module (1), its characterized in that: the power detection module (1) is used for monitoring the electric power on the access electric wire in real time, the power detection module (1) is electrically connected with the processor (2), the processor (2) is electrically connected with the power control module (3), the processor (2) is used for processing the monitoring data sent by the power detection module (1) and controlling the power control module (3) to control and adjust the electric power of the circuit, the power control module (3) is electrically connected with the display module (4), and the display module (4) is used for intensively displaying the real-time data of the electric power;

the power detection module (1) comprises a shell (11) and a power detection sensor (12) fixedly installed at the middle part of one end of the inner cavity of the shell (11), a middle wiring (13) is fixedly installed at the middle part of one end of the inner cavity of the shell (11), the middle wiring (13) penetrates through the bottom of the power detection sensor (12) and is electrically connected with the middle wiring (13), a pressing sleeve (14) is respectively installed at two sides of one end of the inner cavity of the shell (11), the pressing sleeves (14) are respectively sleeved at two ends of the middle wiring (13), and a protective sleeve (15) is embedded at the other end of the inner cavity of the shell (11);

an embedded groove (111) is formed in the shell (11), side wall sliding holes (112) are formed in the outer walls of the two sides of the shell (11), the embedded groove (111) is communicated with the side wall sliding holes (112), a first inner embedded groove (113) and a second inner embedded groove (114) are symmetrically formed in the inner cavity of the embedded groove (111) and located on the two sides of the power detection sensor (12), and the second inner embedded groove (114) is located between the side wall sliding holes (112) and the first inner embedded groove (113);

a receiving groove (1111) is arranged on the bottom surface of the inner cavity of the embedding groove (111), and a semicircular clamping block (1112) is elastically and slidably arranged at the opening of the inner cavity of the receiving groove (1111) through a reset spring (1113);

the middle wiring (13) comprises a hard metal wiring (131) and pushing sleeves (132) respectively fixedly sleeved on the outer walls of two ends of the hard metal wiring (131), protruding blocks (133) are respectively fixedly installed on the outer walls of the pushing sleeves (132), inserting pushing blocks (134) are fixedly installed on the outer walls of the protruding blocks (133), and pushing sliding shafts (135) are respectively fixedly installed on the outer walls of the inserting pushing blocks (134).

2. The distributed power access-based power grid power control detection apparatus according to claim 1, wherein: the compressing sleeve (14) comprises a round jacket (141) and compressing sliding blocks (142) which are slidably arranged at the upper end and the lower end of the front end of the inner cavity of the round jacket (141), and the inner end of the round jacket (141) is slidably sleeved on the pushing sleeve (132).

3. The distributed power access-based power grid power control detection apparatus according to claim 2, wherein: the middle part department of circular overcoat (141) is provided with T type round hole (1411), and is provided with elasticity in spout (1412) on the top surface and the bottom surface of T type round hole (1411) inner chamber respectively, and installs extension spring (1413) on elasticity in spout (1412) inner chamber, is provided with restriction in spout (1414) on the top surface and the bottom surface of T type round hole (1411) inner chamber respectively, and is linked together through well slide hole (1415) between restriction in spout (1414) and the elasticity in spout (1412).

4. A distributed power access-based power grid power control detection apparatus according to claim 3, wherein: the protruding block (133) is arranged in the elastic inner sliding groove (1412) in a sliding mode, one end portion of the extension spring (1413) is connected and installed on the outer wall of the protruding block (133), and the pressing sliding blocks (142) are respectively arranged in the limiting inner sliding groove (1414) in a sliding mode.

5. The distributed power access-based power grid power control detection apparatus according to claim 4, wherein: the inner cavity of the pressing sliding block (142) is provided with a pushing groove (1421), inclined sliding grooves (1422) are respectively formed in the inner walls of the two sides of the inner cavity of the pushing groove (1421), and pushing sliding shafts (135) are respectively arranged in the inclined sliding grooves (1422) in a sliding mode.

6. The distributed power access-based power grid power control detection apparatus according to claim 5, wherein: the inner side of the protective sleeve (15) is provided with a protective groove (151), two-way embedded holes (153) are respectively formed in the outer walls of the two ends of the protective sleeve (15), the protective groove (151) is respectively communicated with the two-way embedded holes (153), and a semicircular clamping groove (152) is formed in the bottom surface of the protective sleeve (15).

7. The distributed power access-based power grid power control detection apparatus according to claim 6, wherein: the semicircular clamping blocks (1112) are movably clamped in the semicircular clamping grooves (152) respectively.