CN218180906U - Transducer probe positioning butt-joint carrying platform - Google Patents

Abstract

The utility model discloses a converter probe location butt joint microscope carrier, including the year material platform, the locating plate, horizontal locating piece, vertical positioning piece, lateral sliding pushes away the subassembly, longitudinal sliding pushes away the subassembly, the probe tool, the year material platform has linked firmly the locating plate, the locating plate has linked firmly horizontal locating piece and vertical locating piece, lateral sliding pushes away the subassembly and includes the horizontal movable locating piece, guide arm guide pin bushing subassembly, extension spring and push rod, longitudinal sliding pushes away the subassembly and includes the longitudinal sliding plate, slider slide rail assembly, guide arm guide pin bushing subassembly, longitudinal movable locating piece, extension spring and connecting plate, the probe tool includes the base, spacing guide pillar, a spring, circular telegram plug and detachable probe module, this microscope carrier adopts the unified probe tool cooperation location of specification to connect the accurate location of microscope carrier to the converter, and the cooperation is violently indulged two-way slide and is pushed away the subassembly and is pressed from both sides the converter tightly, and utilize the action of pressing of the vertical direction of probe tool, can realize accurate butt joint and the electrical property switches on, be suitable for every detection station of detection water flow line.

Description

Transducer probe positioning butt joint carrying platform

Technical Field

The utility model relates to an automatic change detection technology field, concretely relates to converter probe location butt joint microscope carrier.

Background

The existing frequency converter manufactured by production needs to perform performance test on each electric connection end, and due to the fact that the number of the electric connection ends is large, all performance tests cannot be completed at one time by one station, a detection assembly line needs to be designed, the frequency converter of the same specification can be used for detecting the performance of each function step by adopting a probe jig of the same specification one by one, and the performance is automatically transmitted to the detection station of the next station, but a quick and convenient positioning carrier platform needs to be specially designed for the probe jig so as to adapt to a quick and efficient detection assembly line, and the detection accuracy is guaranteed.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the purpose: in view of the efficiency and the accuracy that improve converter performance detection in the background art for the cooperation detects the assembly line, we design a converter probe location butt joint microscope carrier, adopt the unified probe tool cooperation location butt joint microscope carrier of specification, realize the accurate location to the converter to the cooperation is violently indulged two-way slip and is pushed away the subassembly and press from both sides the converter tightly, and utilize the action of pressing of the vertical direction of probe tool, can realize accurate butt joint and electrical property and switch on, and is practical convenient.

The technical scheme adopted for solving the problems is as follows:

a frequency converter probe positioning and butt-joint carrying platform comprises a carrying platform, a positioning plate, a transverse positioning block, a longitudinal positioning block, a transverse sliding pushing assembly arranged right opposite to the transverse positioning block, a longitudinal sliding pushing assembly arranged right opposite to the longitudinal positioning block, and a probe jig electrically conducted with an electric connection end of a frequency converter to be tested,

the material carrying platform is arranged on the detection production line, a positioning plate is horizontally and fixedly connected with the upper part of the material carrying platform through a supporting plate, a transverse positioning block and a longitudinal positioning block are vertically and fixedly connected with one corner of the positioning plate and respectively position the frequency converter in the transverse direction and the longitudinal direction,

the transverse sliding pushing component comprises a transverse movable positioning block, a guide rod and guide sleeve component, a tension spring and a push rod, the transverse movable positioning block is fixedly connected with one end of the guide rod, the guide rod is in sliding fit with the guide sleeve in a penetrating and sleeving manner, the other end of the guide rod is fixedly connected with the push rod, the tension spring is connected between the push rod and the guide sleeve, the guide rod pushes the transverse movable positioning block to push the frequency converter under the pulling of the tension spring, when the push rod is pulled outwards by external force, the transverse movable positioning block releases the frequency converter,

the longitudinal sliding pushing component comprises a longitudinal sliding plate, a sliding block sliding rail component, a guide rod and guide sleeve component, a longitudinal movable positioning block, a tension spring and a connecting plate, wherein the sliding block is fixedly connected below the longitudinal sliding press, the sliding block is matched with the sliding rail to slide longitudinally, the longitudinal movable positioning block is fixedly connected to one end of a guide rod, the guide rod is in sliding fit with the guide sleeve in a penetrating way, the other end of the guide rod is fixedly connected with the connecting plate, the tension spring is fixedly connected between the connecting plate and the guide sleeve, the sliding plate pushes the longitudinal movable positioning block to the frequency converter under the action of external force pushing, and the sliding plate is also fixedly connected with a probe jig,

the probe jig comprises a base, at least two limiting guide columns, a spring, an electrifying plug and a detachable and replaceable probe module, wherein the base is fixedly connected to a sliding plate, each limiting guide column is vertically and fixedly connected to the base, the spring is sleeved on the limiting guide columns in a penetrating mode and used for implementing speed reduction buffering on the probe module, the front end face of the electrifying plug is provided with a power supply end which is fixedly connected to the base through a support, and the power supply end of the frequency converter which is positioned completely is horizontally butted and electrically conducted.

Further, the probe module comprises a front probe inserting plate, a plurality of probes, a supporting column and a butt joint socket, wherein the front probe inserting plate is provided with a plurality of probes for a power connection end arranged below the frequency converter in parallel, a limiting sliding sleeve is arranged at the position of the limiting guide pillar in a penetrating and matching mode, the limiting sliding sleeve slides in a penetrating and matching mode with the limiting guide pillar, all the probes are electrically connected with jacks below the butt joint socket, and the butt joint socket is electrically conducted with a plug of a test instrument to obtain a test data signal.

Furthermore, a plurality of anti-abrasion rollers are uniformly arranged on the inner side of the transverse positioning block at intervals and are in contact positioning with the side face of the bottom of the frequency converter in a rolling mode.

Furthermore, two sides of the butt joint socket are also provided with limiting holes, and the limiting holes are in threaded connection positioning with limiting bolts on two sides of the test instrument plug.

Furthermore, the butt joint socket is fixedly connected to the front sounding plugboard through support columns arranged at four corners.

Furthermore, the two sides of the butt joint socket are symmetrically and fixedly connected with clamping blocks which are used for being matched with a clamping mechanism to take and place.

The utility model has the advantages that:

this converter probe location butt joint microscope carrier adopts the unified probe tool cooperation location butt joint microscope carrier of specification, realizes the accurate positioning to the converter to the cooperation is violently indulged two-way sliding and is pushed away the subassembly and press from both sides the converter tightly, and utilizes the action of pressing of the vertical direction of probe tool, can realize accurate butt joint and electrical property and switch on, can be lifted by the carrier on detecting the rivers line and feed, is suitable for every detection station, and is practical convenient.

Drawings

FIG. 1 is a schematic structural diagram illustrating a positioning state of a transducer of a probe positioning and docking platform of the transducer according to the present embodiment;

FIG. 2 is a schematic structural diagram of a positioning and docking carrier of the transducer probe in this embodiment;

FIG. 3 is a schematic structural diagram of the probe module according to the present embodiment;

FIG. 4 is a schematic position diagram of the slider-slide assembly according to the present embodiment;

fig. 5 is a schematic structural diagram of the frequency converter according to the present embodiment;

FIG. 6 is a schematic structural diagram of the docking plug of the present embodiment;

the device comprises a material loading table 1, a positioning plate 2, a longitudinal sliding pushing assembly 3, a probe jig 4, a frequency converter 5, a longitudinal positioning block 6, a transverse movable positioning block 7, a guide rod guide sleeve assembly 8, a guide rod guide sleeve assembly 9, an anti-abrasion roller 10, a transverse positioning block 11, a longitudinal movable positioning block 12, an energizing plug 13, a limiting guide post 13, a spring 14, a longitudinal sliding plate 15, a probe 16, a clamping block 17, a limiting hole 18, a butt joint socket 19, a limiting sliding sleeve 20, a front probe inserting plate 21, a base 22, a pushing block 23, a sliding block sliding rail assembly 24, a power connection end 25, a power supply end 26, a tension spring 27, a connecting seat 28, a mechanical arm 29, a butt joint plug 30, a butt joint pin 31 and a positioning pin 32.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-5, the present embodiment provides a frequency converter probe positioning and docking carrier, which includes a carrier 1, a positioning plate 2, a transverse positioning block 10, a longitudinal positioning block 6, a transverse sliding pushing assembly disposed opposite to the transverse positioning block 10, a longitudinal sliding pushing assembly 3 disposed opposite to the longitudinal positioning block 6, and a probe fixture 4 electrically connected to a power connection terminal 25 of a frequency converter to be tested 5.

Specifically speaking, carry material platform 1 and set up on detecting the assembly line, the top has linked firmly locating plate 2 through the backup pad level, one corner of locating plate 2 has linked firmly horizontal locating piece 10 and longitudinal positioning piece 6 perpendicularly to the horizontal, the vertical implementation location to converter 5 respectively.

Referring to fig. 2, the transverse sliding pushing assembly comprises a transverse movable positioning block 7, a guide rod and guide sleeve assembly 8, a tension spring 27 and a push rod, wherein the transverse movable positioning block 7 is fixedly connected with one end of a guide rod, the guide rod is in sliding fit with the guide sleeve in a penetrating manner, the other end of the guide rod is fixedly connected with the push rod, the tension spring 27 is connected between the push rod and the guide sleeve, the guide rod pushes the transverse movable positioning block 7 to push the frequency converter 5 when the tension spring 27 pulls, and the transverse movable positioning block 7 releases the frequency converter 5 when the push rod pulls outwards under the action of external force.

The longitudinal sliding pushing assembly 3 comprises a longitudinal sliding plate 15, a sliding block sliding rail assembly 24, a guide rod guide sleeve assembly 8, a longitudinal movable positioning block 11, a tension spring 27 and a connecting plate, the longitudinal sliding is fixedly connected with a sliding block below, the sliding block is matched with a sliding rail to longitudinally slide, the longitudinal movable positioning block 11 is fixedly connected to one end of a guide rod, the guide rod is sleeved with the guide sleeve to be in sliding fit, the other end of the guide rod is fixedly connected with the connecting plate, the tension spring 27 is fixedly connected between the connecting plate and the guide sleeve, the sliding plate pushes the longitudinal movable positioning block 11 to push the frequency converter 5 under the action of external force pushing, and the sliding plate is further fixedly connected with a probe jig 4.

Referring to fig. 3 and 4, the probe jig 4 includes a base 22, two limit guide posts 13, a spring 14, an energizing plug 12 and a detachable and replaceable probe module, the base 22 is fixedly connected to the slide plate, each limit guide post 13 is vertically and fixedly connected to the base 22, the spring 14 is sleeved on the limit guide post 13 in a penetrating manner and implements deceleration buffering on the probe module, and the front end face of the energizing plug 12 is provided with a power supply end 26 which is fixedly connected to the base 22 through a support and horizontally faces the positioned frequency converter 5 to implement butt joint and electrical conduction.

In a further embodiment, referring to fig. 4, the probe module includes a front insertion board 21, 8 probes 16, 4 supporting columns and a docking socket 19, the front insertion board 21 is provided with 8 probes 16 facing a power connection end 25 of the lower frequency converter 5 arranged in parallel, a position facing a position of a position limiting guide post 13 is further provided with a position limiting sliding sleeve 20, the position limiting sliding sleeve 20 and the position limiting guide post 13 are sleeved and matched to slide, all the probes 16 are electrically connected with jacks below the docking socket 19, the docking socket 19 is electrically connected with a test instrument plug (not shown in the figure) to obtain a test data signal, particularly, referring to fig. 6, the test instrument is provided with a docking plug 30 through a connecting seat 28 and a mechanical arm 29 in a positioning manner, the docking plug 30 is provided with equal number of docking pins 31 facing a plurality of pin holes provided in the docking socket, and positioning pins 32 on two sides of the docking plug are used for positioning and docking.

In a further embodiment, referring to fig. 2, 6 anti-wear rollers 9 are further disposed inside the transverse positioning block 10 at regular intervals, and are positioned in rolling contact with the bottom side surface of the frequency converter 5.

In a further embodiment, referring to fig. 4, two sides of the docking socket 19 are further provided with a limiting hole 18, and the limiting hole 18 is in threaded connection with a limiting bolt on two sides of the test instrument plug for positioning.

In a further embodiment, and with reference to fig. 4, the docking socket 19 is attached to the front panel 21 by four corner support posts.

In a further embodiment, referring to fig. 4, the two sides of the docking socket 19 are further symmetrically and fixedly connected with clamping blocks 17 for matching with a clamping mechanism to pick and place and replace the probe module.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes, modifications, substitutions and alterations can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art, and the scope of the present invention is defined by the appended claims and their equivalents.

Claims (6)

1. The utility model provides a frequency converter probe location butt joint microscope carrier, includes that year material platform, locating plate, transverse orientation piece, longitudinal orientation piece, just to the transverse sliding who transverse orientation piece arranged push away the subassembly, just to the longitudinal sliding who longitudinal orientation piece arranged push away the subassembly, with the probe tool that awaits measuring the electrical connection end electric property of frequency converter switches on, its characterized in that:

the material carrying platform is arranged on the detection production line, a positioning plate is horizontally and fixedly connected with the upper part of the material carrying platform through a supporting plate, a transverse positioning block and a longitudinal positioning block are vertically and fixedly connected with one corner of the positioning plate and respectively position the frequency converter in the transverse direction and the longitudinal direction,

the transverse sliding pushing component comprises a transverse movable positioning block, a guide rod and guide sleeve component, a tension spring and a push rod, the transverse movable positioning block is fixedly connected with one end of the guide rod, the guide rod is in penetrating and sliding fit with the guide sleeve, the other end of the guide rod is fixedly connected with the push rod, the tension spring is connected between the push rod and the guide sleeve,

the longitudinal sliding pushing component comprises a longitudinal sliding plate, a sliding block sliding rail component, a guide rod and guide sleeve component, a longitudinal movable positioning block, a tension spring and a connecting plate, wherein the sliding block is fixedly connected below the longitudinal sliding press, the sliding block is matched with the sliding rail to slide longitudinally, the longitudinal movable positioning block is fixedly connected to one end of a guide rod, the guide rod is in sliding fit with the guide sleeve in a penetrating way, the other end of the guide rod is fixedly connected with the connecting plate, the tension spring is fixedly connected between the connecting plate and the guide sleeve, the sliding plate pushes the longitudinal movable positioning block to the frequency converter under the action of external force pushing, and the sliding plate is also fixedly connected with a probe jig,

the probe jig comprises a base, at least two limiting guide columns, a spring, an electrifying plug and a detachable and replaceable probe module, wherein the base is fixedly connected to a sliding plate, each limiting guide column is vertically and fixedly connected to the base, the spring is sleeved on the limiting guide columns in a penetrating mode and used for implementing speed reduction buffering on the probe module, the front end face of the electrifying plug is provided with a power supply end which is fixedly connected to the base through a support, and the power supply end of the frequency converter which is positioned completely is horizontally butted and electrically conducted.

2. The transducer probe positioning docking stage of claim 1, wherein: the probe module comprises a front probe inserting plate, a plurality of probes, a supporting column and a butt joint socket, wherein the front probe inserting plate is provided with a plurality of probes right at a power connection end where a frequency converter below is arranged in parallel, a limiting sliding sleeve is also arranged right at a position of a limiting guide pillar, the limiting sliding sleeve and the limiting guide pillar are sleeved and matched to slide, all the probes are electrically connected with jacks below the butt joint socket, and the butt joint socket is electrically conducted with a plug of a test instrument to obtain a test data signal.

3. The transducer probe positioning docking stage of claim 1, wherein: and a plurality of anti-abrasion rollers are uniformly arranged on the inner side of the transverse positioning block at intervals.

4. The transducer probe positioning docking stage of claim 2, wherein: and limiting holes are also formed in the two sides of the butt joint socket and are in threaded connection positioning with the limiting bolts on the two sides of the test instrument plug.

5. The transducer probe positioning docking stage of claim 2, wherein: the butt joint socket is fixedly connected to the front sounding plugboard through support columns arranged at four corners.

6. The transducer probe positioning docking stage of claim 2, wherein: the butt joint socket both sides still symmetry link firmly the joint piece.

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