CN110116102B - Distribution transformer monitoring terminal letter sorting draws platform - Google Patents

Abstract

The invention discloses a distribution transformer monitoring terminal sorting and extracting platform which comprises a supporting unit, an extracting unit and a transmitting unit, wherein the supporting unit comprises a supporting steel frame and an electric box, and the electric box is installed at one end of the supporting steel frame; the extracting unit comprises a guide rail assembly, a sorting extracting assembly and a driving assembly, wherein the guide rail assembly is arranged at the top end of the supporting steel frame, the sorting extracting assembly is arranged on the guide rail assembly, and the guide rail assembly and the sorting extracting assembly are driven by the driving assembly; the conveying unit comprises a conveying frame and a transfer case, the conveying frame is matched with the supporting steel frame, and the transfer case is conveyed on the conveying frame; according to the invention, the sorting matching plug is adapted to the sockets of different models, the adapted distribution transformer monitoring terminal is quickly extracted by the extraction piece and placed in a specified area, and in the extraction process, the anti-falling structure in the extraction piece is started to protect the distribution transformer monitoring terminal.

Description

Distribution transformer monitoring terminal letter sorting draws platform

Technical Field

The invention relates to the technical field of distribution detection production lines, in particular to a distribution transformer monitoring terminal sorting and extracting platform.

Background

Distribution transformer monitor terminal is also known as TTU, and TTU can carry out relevant inspection and test after accomplishing the assembly, detects the completion, need classify to the terminal of different models, and the classification process is gone on the assembly line usually, is guaranteeing the efficiency among the quick classification process simultaneously under the prerequisite of sufficient rate of accuracy. In the classification process, the models of the distribution transformer monitoring terminals need to be distinguished, after the distinguishing is completed, the extraction platform extracts the distribution transformer monitoring terminals of the same model, and the extracted distribution transformer monitoring terminals are movably placed in a specified area. In current letter sorting draws the platform, can carry out the differentiation of different interfaces to different model distribution transformer detection terminal, then utilize multiple equipment to make up the differentiation together, but in this method, multiple equipment can increase the cost of letter sorting process, and the branch work of while multiple equipment also can influence the efficiency of letter sorting to a certain extent. Therefore, there is a need for a simplified and improved sorting process.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The invention is provided in view of the problems of the existing distribution transformer monitoring terminal sorting and extracting platform.

Therefore, the invention aims to provide a distribution transformer monitoring terminal sorting and extracting platform which is used for solving the problem of how to simplify the sorting and extracting process of the distribution transformer monitoring terminals.

In order to solve the technical problems, the invention provides the following technical scheme: a distribution transformer monitoring terminal sorting and extracting platform comprises a supporting unit, an extracting unit and a conveying unit, wherein the supporting unit comprises a supporting steel frame and an electric box, and the electric box is installed at one end of the supporting steel frame; the extraction unit comprises a guide rail assembly, a sorting extraction assembly and a driving assembly, wherein the guide rail assembly is arranged at the top end of the support steel frame, the sorting extraction assembly is arranged on the guide rail assembly, and the guide rail assembly and the sorting extraction assembly are driven by the driving assembly; the conveying unit comprises a conveying frame and a transfer box, the conveying frame is installed in a matched mode with the supporting steel frame, and the transfer box is conveyed on the conveying frame.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the supporting steel frame is formed by welding steel, the adjacent supporting legs are reinforced by welding steel, and the bottom of each supporting leg is provided with a bearing gasket.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the width of electric box is less than the width that supports the steelframe, and its installation is between two supporting legs that support steelframe one end.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the guide rail subassembly divide into transverse guide subassembly and longitudinal rail subassembly, the transverse guide subassembly is on a parallel with the top plane setting that supports the steelframe, the longitudinal rail subassembly is connected on the transverse guide subassembly, and the perpendicular to supports the top plane setting of steelframe.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the transverse guide rail assembly comprises a first transverse rail, a second transverse rail, a third transverse rail and sliding blocks, the first transverse rail and the second transverse rail are arranged on a long edge of the plane of the top of the supporting steel frame in parallel, the sliding blocks are symmetrically arranged at the bottoms of the two ends of the third transverse rail and are respectively connected to the upper ends of the first transverse rail and the second transverse rail in a sliding mode, and the sliding blocks are arranged at the upper ends of the third transverse rail.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the longitudinal guide rail assembly comprises a longitudinal guide rail and a connecting slide block, the connecting slide block is arranged on the longitudinal guide rail, and the connecting slide block is connected with the slide block of the third transverse rail.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the sorting and extracting assembly is arranged at the bottom end of the longitudinal guide rail and comprises an extracting part and a sorting and matching plug, the extracting part comprises a bidirectional cylinder, a grabbing plate and an anti-disengaging structure, the grabbing plate is symmetrically arranged on two sides of the bidirectional cylinder, and the anti-disengaging structure is arranged on one side, far away from the bidirectional cylinder, of the grabbing plate; sorting mating plug sets up in the bottom middle part of two-way cylinder, and its grafting portion is formed by a plurality of plug connector array, the plug connector includes connecting cylinder, spacing spring and sleeve, the inside of connecting cylinder is cavity, has evenly seted up a plurality of spring grooves, spacing spring is installed separately to the spring inslot, the one end and the sleeve fixed connection of connecting cylinder are kept away from to spacing spring, and one-to-one, the bar groove has been seted up on the telescopic lateral wall, and it cup joints in the outside of connecting cylinder, and from big to little nested connection in proper order between the sleeve.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: anti-disengaging structure includes connecting axle, torsional spring, head rod, second connecting rod, roller and telescopic link, the torsional spring has been cup jointed to the both ends symmetry of connecting axle, the both ends of torsional spring link to each other with head rod, second connecting rod respectively, and the head rod keeps away from the one end of torsional spring and articulates on the lateral wall of grabhook board, the one end that the torsional spring was kept away from to the second connecting rod links to each other with the roller, the middle part of connecting axle links to each other with the flexible end of telescopic link, the stiff end of telescopic link is fixed on the lateral wall of grabhook board.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the drive assembly divide into plane drive assembly and lift drive assembly, lift drive assembly installs among the plane drive assembly, just plane drive assembly includes transverse drive spare and radial driving spare, transverse drive spare sets up the one end at first horizontal rail, radial driving spare sets up the one end at the third horizontal rail, lift drive assembly installs at the top that is located third horizontal rail upper end slider.

As an optimal scheme of the distribution transformer monitoring terminal sorting and extracting platform, the distribution transformer monitoring terminal sorting and extracting platform comprises the following steps: the structure of transverse driving spare, radial driving spare and lift drive assembly is the same, wherein transverse driving spare includes diversion gear set, belt pulley, belt and driving motor, diversion gear set fixes the one end at first horizontal rail, diversion gear set's input shaft belt pulley, the belt pulley passes through the belt and connects at driving motor's output.

The invention has the beneficial effects that: according to the invention, the sorting matching plug is adapted to the sockets of different models, the adapted distribution transformer monitoring terminal is quickly extracted by the extraction piece and placed in a specified area, and in the extraction process, the anti-falling structure in the extraction piece is started to protect the distribution transformer monitoring terminal.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is a schematic view of the overall structure of a distribution transformer monitoring terminal sorting and extracting platform of the invention.

Fig. 2 is a schematic overall side view structure diagram of the distribution transformer monitoring terminal sorting and extracting platform of the invention.

Fig. 3 is a schematic view of a supporting unit top connection structure of the distribution transformer monitoring terminal sorting and extracting platform of the present invention.

Fig. 4 is a schematic diagram of an extraction unit structure of the distribution transformer monitoring terminal sorting extraction platform of the present invention.

Fig. 5 is a schematic view of an anti-falling structure of the distribution transformer monitoring terminal sorting and extracting platform of the invention.

Fig. 6 is a schematic diagram of the overall structure of the sorting matching plug of the sorting extraction platform of the distribution transformer monitoring terminal.

Fig. 7 is a schematic diagram of a separation structure of plug-in pieces in a sorting matching plug of the sorting and extracting platform of the distribution transformer monitoring terminal of the invention.

Fig. 8 is a schematic diagram of a cross rail driving structure of the distribution transformer monitoring terminal sorting and extracting platform of the present invention.

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, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Furthermore, the present invention is described in detail with reference to the drawings, and in the detailed description of the embodiments of the present invention, the cross-sectional view illustrating the structure of the device is not enlarged partially according to the general scale for convenience of illustration, and the drawings are only exemplary and should not be construed as limiting the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in the actual fabrication.

Example 1

Referring to fig. 1, for the first embodiment of the present invention, a distribution transformer monitoring terminal sorting and extracting platform is provided, which includes a supporting unit 100, an extracting unit 200, and a transmitting unit 300, wherein the supporting unit 100 includes a supporting steel frame 101 and an electrical box 102, and the electrical box 102 is installed at one end of the supporting steel frame 101; the extracting unit 200 comprises a guide rail assembly 201, a sorting extracting assembly 202 and a driving assembly 203, wherein the guide rail assembly 201 is arranged at the top end of the supporting steel frame 101, the sorting extracting assembly 202 is arranged on the guide rail assembly 201, and the guide rail assembly 201 and the sorting extracting assembly 202 are driven by the driving assembly 203; the conveying unit 300 comprises a conveying frame 301 and a transfer box 302, wherein the conveying frame 301 is matched with the supporting steel frame 101, and the transfer box 302 is conveyed on the conveying frame 301.

The supporting steel frame 101 is used for providing an installation frame, the electric box 102 is installed at one end of the supporting steel frame 101, the electric box 102 is used for installing electrical equipment required by a platform, the guide rail assembly 201 in the extraction unit 200 is a track for the sorting extraction assembly 202 to move, the driving assembly 203 respectively provides driving force for the guide rail assembly 201 and the sorting extraction assembly 202, the conveying frame 301 in the conveying unit 300 is used for conveying the transfer box 302, and the transfer box 302 stores a distribution transformer monitoring terminal; the conveying frame 301 is installed inside the supporting steel frame 101 in a matching manner, one end of the conveying frame is close to the electric box 102, wherein the conveying frame 301 is divided into an upper layer and a lower layer, the upper layer is longer than the lower layer in length, the upper layer is used for conveying the transfer boxes 302 to be sorted, and the lower layer is used for conveying the transfer boxes 302 after sorting.

In use, the supporting steel frame 101 is installed at one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the rail unit 201, the sorting and extracting assembly 202 is installed in the rail assembly 201, the rail assembly 201 is driven by installing the driving assembly 203, the transfer box 302 is conveyed in the conveying frame 301, and the sorting and extracting assembly 202 corresponds to the transfer box.

Example 2

Referring to fig. 1 and 2, a second embodiment of the present invention, which is different from the first embodiment, is: the supporting steel frame 101 is formed by welding steel materials, adjacent supporting legs are reinforced by welding steel materials, and supporting gaskets are installed at the bottoms of the supporting legs. The width of the electrical box 102 is smaller than that of the supporting steel frame 101, and the electrical box is installed between two supporting legs at one end of the supporting steel frame 101.

Compared with the embodiment 1, the supporting steel frame 101 is not integrally formed but welded by steel, so that the plasticity of the supporting steel frame 101 is increased, the bottom of each supporting leg is provided with a bearing gasket, the stability of the supporting steel frame can be increased, the pressure on the ground can be reduced, and meanwhile, a touch control operation screen is arranged on a cross bar at the top of the supporting steel frame 101 and used for controlling the whole device; the width of the electrical box 102 is smaller than that of the supporting steel frame 101, and the electrical box 102 is matched and installed inside the supporting steel frame 101.

The rest of the structure is the same as that of embodiment 1.

In the using process, the supporting steel frames 101 are formed by welding steel materials, the completed supporting steel frames 101 are installed in a designated area, the supporting steel frames 101 are close to one end of the conveying unit 300, the top ends of the supporting steel frames 101 are used for installing the rail unit 201, the sorting and extracting assemblies 202 are installed in the guide rail assemblies 201, the guide rail assemblies 201 are driven through the installation driving assemblies 203, the conveying unit 300 is installed inside the supporting steel frames 101 in a matched mode, the transfer boxes 302 are conveyed in the conveying frame 301, and the sorting and extracting assemblies 202 correspond to the transfer boxes.

Example 3

Referring to fig. 2 and 3, a third embodiment of the present invention, which is different from the second embodiment, is: the guide rail assembly 201 is divided into a transverse guide rail assembly 201a and a longitudinal guide rail assembly 201b, the transverse guide rail assembly 201a is arranged in parallel to the top end plane of the supporting steel frame 101, and the longitudinal guide rail assembly 201b is connected to the transverse guide rail assembly 201a and is arranged perpendicular to the top end plane of the supporting steel frame 101.

Further, compared to embodiment 2, the rail assembly 201 is divided into a transverse rail assembly 201a and a longitudinal rail assembly 201b, the transverse rail assembly 201a is used for movement in a transverse plane, and the longitudinal rail assembly 201b is capable of longitudinal lifting movement based on the transverse plane.

The rest of the structure is the same as that of embodiment 2.

In the using process, the steel materials are welded to form a supporting steel frame 101, the completed supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the rail unit 201, the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, the longitudinal guide rail assembly 201b is vertically installed in the transverse guide rail assembly 201a, the sorting and extracting assembly 202 is installed at the bottom end of the longitudinal guide rail assembly 201b, the driving assembly 203 is installed to drive the guide rail assembly 201, the conveying unit 300 is installed inside the supporting steel frame 101 in a matching mode, the transfer box 302 is conveyed in the conveying frame 301, and the sorting and extracting assembly 202 corresponds to the transfer box.

Example 4

Referring to fig. 1 to 3 and 8, a fourth embodiment of the present invention is different from the third embodiment in that: the transverse guide rail assembly 201a comprises a first transverse rail 201a-1, a second transverse rail 201a-2, a third transverse rail 201a-3 and a sliding block 201a-4, the first transverse rail 201a-1 and the second transverse rail 201a-2 are arranged on the long edge of the top plane of the supporting steel frame 101 in parallel, the sliding blocks 201a-4 are symmetrically arranged at the bottoms of the two ends of the third transverse rail 201a-3, the two sliding blocks 201a-4 are respectively connected to the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2 in a sliding mode, and meanwhile the sliding block 201a-4 is arranged at the upper end of the third transverse rail 201 a-3.

The rest of the structure is the same as that of example 3.

Compared with embodiment 3, further, the transverse guide assembly 201a includes three parts, namely a first transverse rail 201a-1, a second transverse rail 201a-2 and a third transverse rail 201a-3, the three transverse rails have the same structure, a screw rod is rotatably disposed inside the transverse rails, the screw rod is rotatably sleeved with a slider 201a-4, as shown in the figure, wherein the third transverse rail 201a-3 is shorter than the other two transverse rails, the first transverse rail 201a-1 and the second transverse rail 201a-2 have the same length and are parallelly mounted on the upper end of the long side of the top plane of the supporting steel frame 101, two ends of the third transverse rail 201a-3 are respectively fixed on the sliders 201a-4 on the first transverse rail 201a-1 and the second transverse rail 201a-2, the three transverse rails have the same structure, the screw rod is disposed inside the rails, and the screw rod is matched with the slider 201a-4 for rotation, the driving slider 201a-4 is driven to move on the cross rail.

In the using process, the steel materials are welded to form a supporting steel frame 101, the completed supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the rail unit 201, wherein the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, the first transverse rail 201a-1 and the second transverse rail 201a-2 are installed at the upper end of the long edge of the top plane of the supporting steel frame 101 in parallel, the two ends of the third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, the longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, the bottom end of the longitudinal guide rail assembly 201b is provided with the sorting and extracting assembly 202, the driving assembly 203 is installed to drive the guide rail assembly 201, the conveying unit 300 is installed inside the supporting steel frame, the transfer rack 301 transfers the transfer boxes 302 therein so that the sorting and extracting elements 202 correspond thereto.

Example 5

Referring to fig. 2 and 4, a fifth embodiment of the present invention, which is different from the fourth embodiment, is: the longitudinal guide rail assembly 201b comprises a longitudinal guide rail 201b-1 and a connecting sliding block 201b-2, the connecting sliding block 201b-2 is arranged on the longitudinal guide rail 201b-1, and the connecting sliding block 201b-2 is connected with the sliding block 201a-4 of the third transverse rail 201 a-3.

Compared with the embodiment 4, further, only one longitudinal guide rail 201b-1 is arranged in the longitudinal guide rail assembly 201b, the upper end of the longitudinal guide rail 201b-1 is connected with the connecting slider 201b-2, the connecting slider 201b-2 is fixedly connected with the slider 201a-4 on the third transverse rail 201a-3, and the longitudinal guide rail 201b-1 can reciprocate up and down in the connecting slider 201b-2, wherein the longitudinal guide rail 201b-1 is connected with the connecting slider 201b-2 in an existing mechanical manner, a single-side rack is arranged on a side wall of the longitudinal guide rail 201b-1, which is in contact with the connecting slider 201b-2, and the lifting driving of the longitudinal guide rail 201b-1 can be realized by mounting a gear on an output end of a driving part mounted on the connecting slider 201 b-2.

The rest of the structure is the same as that of example 4.

In the using process, the supporting steel frame 101 is formed by welding steel materials, the finished supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the track unit 201, wherein the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, the first transverse rail 201a-1 and the second transverse rail 201a-2 are installed at the upper end of the long side of the top plane of the supporting steel frame 101 in parallel, the two ends of the third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, the longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, the connecting slider 201b-2 is fixedly connected to the upper end of the slider 201a-4 on the third transverse rail 201a-3, the longitudinal guide rail 201b-1 is installed in the connecting slider 201b-2, and a sorting and extracting assembly 202 is installed at the bottom end of the longitudinal guide rail 201b-1, and the guide rail assembly 201 is driven by installing a driving assembly 203, the conveying unit 300 is fittingly installed inside the supporting steel frame 101, the transfer box 302 is conveyed in the conveying frame 301, and the sorting and extracting assembly 202 corresponds thereto.

Example 6

Referring to fig. 4 to 6, a sixth embodiment of the present invention is different from the fifth embodiment in that: the sorting and extracting assembly 202 is arranged at the bottom end of the longitudinal guide rail 201b-1 and comprises an extracting part 202a and a sorting and matching plug 202b, the extracting part 202a comprises a bidirectional cylinder 202a-1, a grabbing plate 202a-2 and an anti-falling structure 202a-3, the grabbing plate 202a-2 is symmetrically arranged on two sides of the bidirectional cylinder 202a-1, and the anti-falling structure 202a-3 is arranged on one side, away from the bidirectional cylinder 202a-1, of the grabbing plate 202 a-2; the sorting matching plug 202b is arranged in the middle of the bottom end of the bidirectional cylinder 202a-1, the plugging portion of the plug is formed by a plurality of plug connector arrays, each plug connector comprises a connecting cylinder 202b-1, a limiting spring 202b-2 and a sleeve 202b-3, the connecting cylinder 202b-1 is hollow, a plurality of spring grooves 202b-11 are uniformly formed in the connecting cylinder 202b-1, the limiting springs 202b-2 are respectively arranged in the spring grooves 202b-11, one ends, far away from the connecting cylinder 202b-1, of the limiting springs 202b-2 are fixedly connected with the sleeves 202b-3 in a one-to-one correspondence mode, the side walls of the sleeves 202b-3 are provided with strip-shaped grooves 202b-31 which are sleeved on the outer side of the connecting cylinder 202b-1, and the sleeves 202b-3 are sequentially connected in a nesting mode.

Compared with the embodiment 3, further, the sorting matching plug 202b in the sorting extraction assembly 202 is used for distinguishing different types of terminals through matching sockets, and the extraction piece 202a is used for extracting the identified terminals, wherein the limiting springs 202b-2 and the sleeves 202b-3 in the sorting matching plug 202b are in one-to-one correspondence, the corresponding lengths of the two are the same, and the length of the inner sleeve 202b-3 is longer than that of the outer sleeve 202b-3 between the nested sleeves 202 b-3; the connecting part of the limiting spring 202b-2 and the sleeve 202b-3 moves in the strip-shaped groove 202b-31 in a limiting way; when the limiting springs 202b-2 are all at the initial length, the connecting cylinder 202b-1 and the bottom end of each sleeve 202b-3 are located in the same horizontal plane.

The rest of the structure is the same as that of example 5.

In the using process, the supporting steel frame 101 is formed by welding steel materials, the finished supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the track unit 201, wherein the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, the first transverse rail 201a-1 and the second transverse rail 201a-2 are installed at the upper end of the long side of the top plane of the supporting steel frame 101 in parallel, the two ends of the third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, the longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, the connecting slider 201b-2 is fixedly connected to the upper end of the slider 201a-4 on the third transverse rail 201a-3, the longitudinal guide rail 201b-1 is installed in the connecting slider 201b-2, and a sorting extraction assembly 202 is installed at the bottom end of the longitudinal guide 201 b-1.

In the sorting and extracting assembly 202, a sorting matching plug 202b is arranged in the middle of the bottom end of the extracting piece 202a, each sleeve 202b-3 in the sorting matching plug 202b is sequentially nested on the outer wall of the connecting cylinder 202b-1 from long to short, and a connecting spring 202b-2 in the inner wall of the connecting cylinder 202b-1 is connected with the corresponding sleeve 202 b-3; and drives the guide rail assembly 201 by installing the driving assembly 203, the conveying unit 300 is installed inside the supporting steel frame 101 in a matching way, the transfer box 302 is conveyed in the conveying frame 301, and the sorting and extracting assembly 202 corresponds to the transfer box.

Example 7

Referring to fig. 4 and 7, a seventh embodiment of the present invention, which is different from the sixth embodiment, is: the anti-falling structure 202a-3 comprises connecting shafts 202a-31, torsion springs 202a-32, first connecting rods 202a-33, second connecting rods 202a-34, rollers 202a-35 and telescopic rods 202a-36, wherein the torsion springs 202a-32 are symmetrically sleeved at two ends of the connecting shafts 202a-31, two ends of the torsion springs 202a-32 are respectively connected with the first connecting rods 202a-33 and the second connecting rods 202a-34, and one ends of the first connecting rods 202a-33 far away from the torsion springs 202a-32 are hinged on the side wall of the gripping plate 202a-2, one ends of the second connecting rods 202a-34 far away from the torsion springs 202a-32 are connected with the rollers 202a-35, the middle parts of the connecting shafts 202a-31 are connected with the telescopic ends of the telescopic rods 202a-36, and the fixed ends of the telescopic rods 202a-36 are fixed on the side wall of the gripping plate 202 a-2.

Compared with the embodiment 6, further, the ends of the first connecting rods 202a-33 and the second connecting rods 202a-34, which are in contact with each other, are sleeved on two ends of the connecting shafts 202a-31 and are respectively connected with one end of the torsion springs 202a-32, the two connecting rods are distributed in a V shape, two ends of the rollers 202a-35 are respectively and rotatably connected to the second connecting rods 202a-33, and in the initial state of the torsion springs 202a-32, one side of the rollers 202a-35 and one side of the grasping plate 202a-2, which is close to the bidirectional cylinder 202a-1, are in the same plane, the rollers 202a-35 are used for contracting the telescopic rods 202a-36 when grasping the terminal end, so as to press the torsion springs 202a-32 to be opened and closed, so as to press the rollers 202a-35 to move along the side walls of the terminal, when the rollers 202a-35 move to, when the movement is stopped, the rollers 202a-35 can provide an upward acting force for the terminal to prevent the terminal from falling off when the grabbing plate 202a-2 grabs the terminal to move up and down or is suspended; the telescopic rods 202a-36 are hinged to the middle of the side wall of the grabbing plate 202a-2, and the middle of the grabbing plate 202a-2 is provided with a receiving groove for receiving the telescopic rods 202 a-36.

The rest of the structure is the same as that of example 6.

In the using process, all steel materials are welded to form a supporting steel frame 101, the completed supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the conveying unit 300 is installed inside the supporting steel frame 101 in a matching mode, the transfer box 302 is conveyed in the conveying frame 301, and the sorting and extracting assembly 202 corresponds to the transfer box; the top end of the supporting steel frame 101 is used for installing a rail unit 201, wherein a transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, a first transverse rail 201a-1 and a second transverse rail 201a-2 are installed at the upper end of the long edge of the top plane of the supporting steel frame 101 in parallel, two ends of a third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, a longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, wherein a connecting slider 201b-2 is fixedly connected to the upper end of a slider 201a-4 on the third transverse rail 201a-3, the longitudinal guide rail 201b-1 is installed in the connecting slider 201b-2, and a sorting and extracting assembly 202 is installed at the bottom end of the longitudinal guide rail 201 b-1;

in the sorting and extracting assembly 202, a sorting matching plug 202b is arranged in the middle of the bottom end of the extracting piece 202a, each sleeve 202b-3 in the sorting matching plug 202b is sequentially nested on the outer wall of the connecting cylinder 202b-1 from long to short, and a connecting spring 202b-2 in the inner wall of the connecting cylinder 202b-1 is connected with the corresponding sleeve 202 b-3; after the sorting matching plug 202b is matched, the extracting piece 202a works, the bidirectional cylinder 202a-1 pushes the grabbing plate 202a-2 to open and clamp the terminal, and then the anti-falling structures 202a-3 on the two sides of the grabbing plate 202a-2 work to perform anti-falling protection on the clamped terminal. And drives the guide rail assembly 201 to move by mounting the drive assembly 203 for moving the picking and extraction assembly 202 to a designated position.

Example 8

Referring to fig. 2 to 4, an eighth embodiment of the present invention is different from the seventh embodiment in that: the driving assembly 203 is divided into a plane driving assembly 203a and a lifting driving assembly 203b, the lifting driving assembly 203b is installed in the plane driving assembly 203a, the plane driving assembly 203a comprises a transverse driving member 203a-1 and a radial driving member 203a-2, the transverse driving member 203a-1 is arranged at one end of the first transverse rail 201a-1, the radial driving member 203a-2 is arranged at one end of the third transverse rail 201a-3, and the lifting driving assembly 203b is installed at the top of the sliding block 201a-4 at the upper end of the third transverse rail 201 a-3.

Compared with the embodiment 7, further, the driving assembly 203 is divided into a plane driving assembly 203a and a lifting driving assembly 203b, the plane driving assembly 203a is used for driving the movement in the plane, and the lifting driving assembly 203b is used for driving the lifting of the longitudinal guide rail 201b-1, so as to drive the sorting and extracting assembly to work; the plane driving component 203a is divided into a horizontal direction and a radial direction which respectively correspond to the length and the width of the top of the supporting steel frame 101; the transverse driving member 203a-1 is arranged at one end of the first transverse rail 201a-1, and the end of the first transverse rail 201a-1 is synchronously connected with the same side of the second transverse rail 201a-2 by using a connecting shaft, so that the transverse driving member 203a-1 drives the first transverse rail 201a-1 and the second transverse rail 201a-2 to synchronously move; the radial actuator 203a-2 is mounted at one end of the third transverse rail 201a-3 and is only used to actuate the movement of the slider 201a-4 on the third transverse rail 201 a-3.

The rest of the structure is the same as that of example 7.

In the using process, the supporting steel frame 101 is formed by welding steel materials, the finished supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the track unit 201, wherein the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, the first transverse rail 201a-1 and the second transverse rail 201a-2 are installed at the upper end of the long side of the top plane of the supporting steel frame 101 in parallel, the two ends of the third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, the longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, the connecting slider 201b-2 is fixedly connected to the upper end of the slider 201a-4 on the third transverse rail 201a-3, the longitudinal guide rail 201b-1 is installed in the connecting slider 201b-2, and a sorting extraction assembly 202 is installed at the bottom end of the longitudinal guide 201 b-1.

In the sorting and extracting assembly 202, a sorting matching plug 202b is arranged in the middle of the bottom end of the extracting piece 202a, each sleeve 202b-3 in the sorting matching plug 202b is sequentially nested on the outer wall of the connecting cylinder 202b-1 from long to short, and a connecting spring 202b-2 in the inner wall of the connecting cylinder 202b-1 is connected with the corresponding sleeve 202 b-3; after the sorting matching plug 202b is matched, the extracting piece 202a works, the bidirectional cylinder 202a-1 pushes the grabbing plate 202a-2 to open and clamp the terminal, and then the anti-falling structures 202a-3 on the two sides of the grabbing plate 202a-2 work to perform anti-falling protection on the clamped terminal. And drives the guide rail assembly 201 to move by mounting the drive assembly 203 for moving the picking and extraction assembly 202 to a designated position. In the driving process, the transverse driving member 203a-1 drives the first transverse rail 201a-1 to move, the radial driving member 203a-2 drives the third transverse rail 201a-3 to move, and the lifting driving assembly 203b drives the longitudinal guide rail 201b-1 to move up and down.

Example 9

Referring to fig. 3 and 8, a ninth embodiment of the present invention, which is different from the eighth embodiment, is: the transverse driving member 203a-1, the radial driving member 203a-2 and the lifting driving assembly 203b are identical in structure, wherein the transverse driving member 203a-1 comprises a direction-changing gear set 203a-11, pulleys 203a-12, a belt 203a-13 and driving motors 203a-14, the direction-changing gear set 203a-11 is fixed at one end of the first transverse rail 201a-1, an input shaft of the direction-changing gear set 203a-11 is connected with the pulleys 203a-12, and the pulleys 203a-12 are connected at output ends of the driving motors 203a-14 through the belts 203 a-13.

Compared with the embodiment 8, further, the structure of the transverse driving element 203a-1, the radial driving element 203a-2 and the lifting driving assembly 203b is the same, taking the transverse driving element 203a-1 as an example, the output end of the direction-changing gear set 203a-11 is connected with a screw rod in a guide rail, a protective frame is arranged outside the belt 203a-13 and the belt pulley 203a-12, the driving motor 203a-14 is fixed on the outer wall of the protective frame, the driving motor 203a-14 drives the belt pulley 203a-12 to rotate through the belt 203a-13, and then drives the screw rod to rotate through the direction-changing gear set 203a-11, so as to drive the sliding block 201a-4 to move on the transverse rail.

The rest of the structure is the same as that of example 8.

In the using process, the supporting steel frame 101 is formed by welding steel materials, the finished supporting steel frame 101 is installed in a designated area, the supporting steel frame 101 is close to one end of the conveying unit 300, the top end of the supporting steel frame 101 is used for installing the track unit 201, wherein the transverse guide rail assembly 201a is installed at the top of the supporting steel frame 101, specifically, the first transverse rail 201a-1 and the second transverse rail 201a-2 are installed at the upper end of the long side of the top plane of the supporting steel frame 101 in parallel, the two ends of the third transverse rail 201a-3 are respectively arranged at the upper ends of the first transverse rail 201a-1 and the second transverse rail 201a-2, the longitudinal guide rail assembly 201b is vertically installed in the third transverse rail 201a-3, the connecting slider 201b-2 is fixedly connected to the upper end of the slider 201a-4 on the third transverse rail 201a-3, the longitudinal guide rail 201b-1 is installed in the connecting slider 201b-2, and a sorting extraction assembly 202 is installed at the bottom end of the longitudinal guide 201 b-1.

In the sorting and extracting assembly 202, a sorting matching plug 202b is arranged in the middle of the bottom end of the extracting piece 202a, each sleeve 202b-3 in the sorting matching plug 202b is sequentially nested on the outer wall of the connecting cylinder 202b-1 from long to short, and a connecting spring 202b-2 in the inner wall of the connecting cylinder 202b-1 is connected with the corresponding sleeve 202 b-3; after the sorting matching plug 202b is matched, the extracting piece 202a works, the bidirectional cylinder 202a-1 pushes the grabbing plate 202a-2 to open and clamp the terminal, and then the anti-falling structures 202a-3 on the two sides of the grabbing plate 202a-2 work to perform anti-falling protection on the clamped terminal. And drives the guide rail assembly 201 to move by mounting the drive assembly 203 for moving the picking and extraction assembly 202 to a designated position. In the driving process, the transverse driving member 203a-1 drives the first transverse rail 201a-1 to move, the radial driving member 203a-2 drives the third transverse rail 201a-3 to move, and the lifting driving assembly 203b drives the longitudinal guide rail 201b-1 to move up and down. During the operation of the transverse driving member 203a-1, the driving motor 203a-14 drives the pulley 203a-12 to rotate through the belt 203a-13, and the pulley 203a-12 indirectly drives the sliding block 201a-4 to move through the direction-changing gear set 203 a-11.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (9)

1. The utility model provides a distribution transformer monitor terminal letter sorting draws platform which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the supporting unit (100) comprises a supporting steel frame (101) and an electric box (102), wherein the electric box (102) is installed at one end of the supporting steel frame (101);

the extraction unit (200) comprises a guide rail assembly (201), a sorting extraction assembly (202) and a driving assembly (203), the guide rail assembly (201) is arranged at the top end of the supporting steel frame (101), the sorting extraction assembly (202) is arranged on the guide rail assembly (201), and the guide rail assembly (201) and the sorting extraction assembly (202) are driven by the driving assembly (203);

the sorting and extracting assembly (202) comprises an extracting piece (202 a) and a sorting and matching plug (202 b), wherein the extracting piece (202 a) comprises a bidirectional air cylinder (202 a-1), a grabbing plate (202 a-2) and a separation preventing structure (202 a-3), the grabbing plate (202 a-2) is symmetrically arranged on two sides of the bidirectional air cylinder (202 a-1), and the separation preventing structure (202 a-3) is arranged on one side, away from the bidirectional air cylinder (202 a-1), of the grabbing plate (202 a-2);

the sorting matching plug (202 b) is arranged in the middle of the bottom end of the bidirectional cylinder (202 a-1), the plugging part of the sorting matching plug is formed by a plurality of plug connectors in an array mode, each plug connector comprises a connecting cylinder (202 b-1), a limiting spring (202 b-2) and a sleeve (202 b-3), the connecting cylinder (202 b-1) is hollow, a plurality of spring grooves (202 b-11) are uniformly formed in the connecting cylinder, the limiting springs (202 b-2) are respectively arranged in the spring grooves (202 b-11), one ends, far away from the connecting cylinder (202 b-1), of the limiting springs (202 b-2) are fixedly connected with the sleeves (202 b-3) and are in one-to-one correspondence, strip-shaped grooves (202 b-31) are formed in the side wall of the sleeves (202 b-3) and are sleeved on the outer side of the connecting cylinder (202 b-1), the sleeves (202 b-3) are sequentially nested and connected from large to small;

the conveying unit (300) comprises a conveying frame (301) and a transfer box (302), wherein the conveying frame (301) is installed in a matched mode with the supporting steel frame (101), and the transfer box (302) is conveyed on the conveying frame (301).

2. The distribution transformer monitoring terminal sorting and extraction platform of claim 1, wherein: the supporting steel frame (101) is formed by welding steel, the adjacent supporting legs are reinforced by welding the steel, and the bottom of each supporting leg is provided with a bearing gasket.

3. The distribution transformer monitoring terminal sorting and extraction platform of claim 1 or 2, wherein: the width of the electric box (102) is smaller than that of the supporting steel frame (101), and the electric box is installed between two supporting feet at one end of the supporting steel frame (101).

4. The distribution transformer monitoring terminal sorting and extraction platform of claim 3, wherein: the guide rail assembly (201) is divided into a transverse guide rail assembly (201 a) and a longitudinal guide rail assembly (201 b), the transverse guide rail assembly (201 a) is arranged in parallel to the top end plane of the supporting steel frame (101), and the longitudinal guide rail assembly (201 b) is connected to the transverse guide rail assembly (201 a) and is perpendicular to the top end plane of the supporting steel frame (101).

5. The distribution transformer monitoring terminal sorting and extraction platform of claim 4, wherein: the transverse guide rail assembly (201 a) comprises a first transverse rail (201 a-1), a second transverse rail (201 a-2), a third transverse rail (201 a-3) and sliding blocks (201 a-4), the first transverse rail (201 a-1) and the second transverse rail (201 a-2) are arranged on the long edge of the top plane of the supporting steel frame (101) in parallel, the sliding blocks (201 a-4) are symmetrically arranged at the bottoms of the two ends of the third transverse rail (201 a-3), the two sliding blocks (201 a-4) are respectively connected to the upper ends of the first transverse rail (201 a-1) and the second transverse rail (201 a-2) in a sliding mode, and meanwhile the sliding blocks (201 a-4) are arranged at the upper end of the third transverse rail (201 a-3).

6. The distribution transformer monitoring terminal sorting and extraction platform of claim 5, wherein: the longitudinal guide rail assembly (201 b) comprises a longitudinal guide rail (201 b-1) and a connecting sliding block (201 b-2), the connecting sliding block (201 b-2) is arranged on the longitudinal guide rail (201 b-1), and the connecting sliding block (201 b-2) is connected with the sliding block (201 a-4) of the third transverse rail (201 a-3).

7. The distribution transformer monitoring terminal sorting and extraction platform of claim 6, wherein: the anti-falling structure (202 a-3) comprises a connecting shaft (202 a-31), torsion springs (202 a-32), first connecting rods (202 a-33), second connecting rods (202 a-34), rollers (202 a-35) and telescopic rods (202 a-36), the torsion springs (202 a-32) are symmetrically sleeved at two ends of the connecting shaft (202 a-31), two ends of the torsion springs (202 a-32) are respectively connected with the first connecting rods (202 a-33) and the second connecting rods (202 a-34), one ends, far away from the torsion springs (202 a-32), of the first connecting rods (202 a-33) are hinged on the side wall of the grabbing plate (202 a-2), one ends, far away from the torsion springs (202 a-32), of the second connecting rods (202 a-34) are connected with the rollers (202 a-35), the middle part of the connecting shaft (202 a-31) is connected with the telescopic end of the telescopic rod (202 a-36), and the fixed end of the telescopic rod (202 a-36) is fixed on the side wall of the grabbing plate (202 a-2).

8. The distribution transformer monitoring terminal sorting and extraction platform of claim 7, wherein: the driving assembly (203) is divided into a plane driving assembly (203 a) and a lifting driving assembly (203 b), the lifting driving assembly (203 b) is installed in the plane driving assembly (203 a), the plane driving assembly (203 a) comprises a transverse driving piece (203 a-1) and a radial driving piece (203 a-2), the transverse driving piece (203 a-1) is arranged at one end of the first transverse rail (201 a-1), the radial driving piece (203 a-2) is arranged at one end of the third transverse rail (201 a-3), and the lifting driving assembly (203 b) is installed at the top of a sliding block (201 a-4) located at the upper end of the third transverse rail (201 a-3).

9. The distribution transformer monitoring terminal sorting and extraction platform of claim 8, wherein: the structure of the transverse driving piece (203 a-1), the structure of the radial driving piece (203 a-2) and the structure of the lifting driving assembly (203 b) are the same, wherein the transverse driving piece (203 a-1) comprises a direction-changing gear set (203 a-11), a belt pulley (203 a-12), a belt (203 a-13) and a driving motor (203 a-14), the direction-changing gear set (203 a-11) is fixed at one end of the first transverse rail (201 a-1), the input shaft of the direction-changing gear set (203 a-11) is connected with the belt pulley (203 a-12), and the belt pulley (203 a-12) is connected at the output end of the driving motor (203 a-14) through the belt (203 a-13).

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