CN218191143U - Detection structure applied to transfer assembly of capacitor glue sleeving machine - Google Patents

Abstract

The utility model provides a detection structure applied to a transfer component of a capacitor laminating machine, which comprises a front detection block and a rear detection block, wherein the front detection block is arranged towards one side of the rear detection block and provided with a detection clamping block A, and the rear detection block is arranged towards one side of the front detection block and provided with a detection clamping block B; a contact block is movably arranged on one side, close to the detection rear block, of the upper surface of the detection clamping block A, and a proximity switch matched with the contact block is arranged on one side, far away from the detection rear block, of the upper surface of the detection front block; the lower part of the contact block is connected with the side surface of the detection clamping block A through a tension spring. The capacitor without the girdling is detected in time, and the reworking of the photoresist removing sleeve in the later period is avoided.

Description

Detection structure applied to transfer assembly of capacitor glue sleeving machine

Technical Field

The utility model relates to an electric capacity processing technology field especially relates to an use and transfer detection structure of subassembly at electric capacity gum machine.

Background

The Chinese patent CN 208180247U, published as 2018, 12 and 04, discloses a capacitor glue coating machine, which comprises a rack, wherein a feeding assembly, a transferring assembly, a disc assembly, a glue coating assembly, a heat shrinkage assembly and a discharging assembly are sequentially arranged on the rack, the disc assembly comprises a disc main body and a disc clamp, the glue coating assembly comprises a pipe conveying mechanism and a sleeve mechanism, the pipe conveying mechanism comprises a rubber pipe disc and a rubber pipe guiding mechanism, the sleeve mechanism comprises a sleeve supporting seat, a sleeve sliding rod, a rubber pipe fixing platform provided with a rubber pipe clamp, a fixing upper plate provided with a guiding sleeve, and the sleeve moving assembly comprises a moving support, a sleeve transverse rod, a sliding block, an upper mold needle, a pipe pressing sleeve, a pipe pressing connecting block fixed outside the pipe pressing sleeve and a pipe pressing rod. The capacitor at the feeding assembly is moved to a corresponding position by using the transfer assembly and the disc assembly, and orderly gluing of the capacitor is realized by using the reciprocating motion of the rubber tube clamp, the guide sleeve and the upper mould needle; the labor is saved, the damage caused by manual operation is avoided, and the production efficiency is improved. In the transfer assembly, the capacitor on the flat conveying rail 12 is firstly moved to the fork foot module 25, two pins of the capacitor are separated by the fork foot piece 251 and the fork foot auxiliary piece 253 and are fixed between the fork foot front block 252 and the fork foot rear block 254, then the capacitor on the fork foot module 25 is moved to the pin adjusting module 26 by the next set of chuck 217, the pins of the capacitor are pressed into a fixed shape by the pin adjusting plate 262 and the pin adjusting pressing plate 263, the capacitor on the pin adjusting module 26 is further moved to a position between the detection front block 271 and the detection rear block 272 of the detection module 27, whether the capacitor is good or not is detected, then the capacitor is moved to the reversing module 28 arranged behind the detection module 27, if the capacitor is detected to be good, the reversing module 28 is not rotated, the capacitor is directly moved to the next detection module 27, if the capacitor is bad, the positions of the positive and negative pins of the capacitor are exchanged, then the capacitor is moved to the next detection module 27, the capacitor is detected again by one or more detection modules 27, if the capacitor is moved from the last detection module 27 to the upper detection rack 32, the last detection module 32 is moved to the lower chuck 215, and the good clamping plate is not moved, if the capacitor is not moved to the lower chuck 32. It has the following disadvantages: in the actual operation process, some situations that the waist is not carried out exist before the capacitor is glued, whether the waist is carried out is not detected in the detection module in the prior art, and the fact that some capacitors which are not carried out the waist need to be picked out additionally finally is caused to carry out rework.

SUMMERY OF THE UTILITY MODEL

Based on this, an object of the utility model is to provide an use and transfer the detection structure of subassembly at electric capacity cover machine of gluing, restraint the waist and detect the function.

The utility model provides a detection structure applied to a transfer component of a capacitor laminating machine, which comprises a front detection block and a rear detection block, wherein the front detection block is arranged towards one side of the rear detection block and provided with a detection clamping block A, and the rear detection block is arranged towards one side of the front detection block and provided with a detection clamping block B; a contact block is movably arranged on one side, close to the detection rear block, of the upper surface of the detection clamping block A, and a proximity switch matched with the contact block is arranged on one side, far away from the detection rear block, of the upper surface of the detection front block; the lower part of the contact block is connected with the side surface of the detection clamping block A through a tension spring.

Preferably, an inverted U-shaped guide frame for the contact block to penetrate through is arranged on the upper surface of the detection clamping block a.

As a preferred scheme, a guide rail convex groove is formed in the position, corresponding to the contact block, of the upper surface of the detection front block, and a guide sliding block matched with the guide rail convex groove is connected to the lower surface of the contact block; and a tension spring is connected between the guide sliding block and the detection clamping block A.

As a preferred scheme, a waist-shaped hole is formed in the middle of the upper surface of the U-shaped guide frame and close to one side of the contact block, and fool-proof convex grains are arranged on one side, corresponding to the waist-shaped hole, of the upper surface of the contact block.

Preferably, the two opposite sides of the inverted U-shaped guide frame along the length direction thereof are connected with the detection clamping block a through bolts.

The utility model has the advantages that: through the matching of the proximity switch and the contact block, when the capacitor is clamped between the front detection block and the rear detection block for detection, if the contact block is pushed to the proximity switch by the capacitor to start the proximity switch, the capacitor is represented as a non-girdling capacitor, a signal is fed back to the control system, the capacitor is removed in the subsequent process, and if the contact block does not touch the proximity switch, the good product is obtained; will the utility model discloses set up to last a set of detection module, in time will not have the electric capacity of beam waist to detect out, avoid the later stage to go to glue the cover and do over again.

Drawings

Fig. 1 is a perspective view of the present invention.

Fig. 2 is a partial front view of a pre-test block.

FIG. 3 is a partial schematic view of a pre-detection block.

The reference signs are: the detection device comprises a front detection block 10, a rear detection block 11, a proximity switch 12, a guide rail convex groove 13, a contact block 14, a bolt 15, a guide slide block 16, a kidney-shaped hole 17, a fool-proof convex particle 18, an inverted U-shaped guide frame 19, a detection clamping block A20, a detection clamping block B21 and a tension spring 22.

Detailed Description

For further understanding of the features and technical means of the present invention, as well as the specific objects and functions attained by the present invention, the present invention will be described in further detail with reference to the accompanying drawings and the detailed description thereof.

In the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly, e.g., as a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those of ordinary skill in the art.

Referring to fig. 1-3, the present invention provides a detection structure applied to a transfer assembly of a capacitor laminator, comprising a front detection block 10 and a rear detection block 11, wherein a detection clamping block a20 is installed at a side surface of the front detection block 10, which is close to the rear detection block 11, and a detection clamping block B21 is installed at a side surface of the rear detection block 11, which is close to the front detection block 10; a contact block 14 is movably arranged on one side, close to the rear detection block 11, of the upper surface of the detection clamping block A20, and a proximity switch 12 matched with the contact block 14 is arranged on one side, away from the rear detection block 11, of the upper surface of the front detection block 10; the lower part of the contact block 14 is connected with the side surface of the detection clamping block A20 through a tension spring 22, a guide rail convex groove 13 is arranged on the upper surface of the detection front block 10 corresponding to the contact block 14, and a guide sliding block 16 matched with the guide rail convex groove 13 is connected to the lower surface of the contact block 14; a tension spring 22 is connected between the guide slider 16 and the detection clamping block A20.

In the embodiment, through the matching of the proximity switch and the contact block, when the capacitor is clamped between the front detection block and the rear detection block for detection, if the contact block is pushed to the proximity switch by the capacitor to start the proximity switch, the proximity switch represents that the capacitor is a capacitor without girdling, a signal is fed back to the control system, the capacitor is removed in the subsequent process, and if the contact block does not touch the proximity switch, the good product is obtained; will the utility model discloses set up to last a set of detection module, in time will not have the electric capacity of beam waist to detect out, avoid the later stage to go to glue the cover and do over again.

The upper surface of the detection clamping block A20 is provided with an inverted U-shaped guide frame 19 through which the contact block 14 penetrates. Prevent contact block 14 perk through the U-shaped guide frame 19 of falling, ensure that contact block 14 round trip movement under the limiting displacement of U-shaped guide frame 19, because the relative both sides of U-shaped guide frame 19 along its length direction are connected with detection clamp splice A20 through bolt 15, convenient to detach adjusts.

A waist-shaped hole 17 is formed in the middle of the upper surface of the U-shaped guide frame at one side close to the contact block 14, and a foolproof convex particle 18 is arranged on one side of the upper surface of the contact block 14 corresponding to the waist-shaped hole 17. Through the cooperation of waist type hole 17 and prevent slow-witted protruding grain 18, avoid contact block 14 excessively to stretch out, influence the detection effect. In the actual operation in-process, when the extension spring is in conventional non-tensile state, prevent slow-witted nibble 18 and be located waist type hole 17 and lean on the inside wall counterbalance contact of detecting back piece 11 one side, if through long-time the back of using, the elastic tension of extension spring descends, prevent during the non-tensile state slow-witted nibble 18 and be located waist type hole 17 and lean on the inside wall counterbalance contact of detecting back piece 11 one side, just need change the extension spring.

The above-mentioned embodiment only expresses one implementation manner of the present invention, and the description thereof is specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the concept of the present invention, several variations and modifications can be made, which all fall within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (5)

1. A detection structure applied to a transfer assembly of a capacitor laminator comprises a front detection block (10) and a rear detection block (11), wherein a detection clamping block A (20) is arranged on one side surface, close to the rear detection block (11), of the front detection block (10), and a detection clamping block B (21) is arranged on one side surface, close to the front detection block (10), of the rear detection block (11);

the method is characterized in that: a contact block (14) is movably arranged on one side, close to the rear detection block (11), of the upper surface of the detection clamping block A (20), and a proximity switch (12) matched with the contact block (14) is arranged on one side, far away from the rear detection block (11), of the upper surface of the front detection block (10); the lower part of the contact block (14) is connected with the side surface of the detection clamping block A (20) through a tension spring (22).

2. The detection structure applied to the transfer component of the capacitor laminator according to claim 1, wherein: the upper surface of the detection clamping block A (20) is provided with an inverted U-shaped guide frame (19) for the contact block (14) to penetrate through.

3. The detection structure applied to the transfer component of the capacitor laminator according to claim 2, wherein: a guide rail convex groove (13) is formed in the position, corresponding to the contact block (14), of the upper surface of the detection front block (10), and a guide sliding block (16) matched with the guide rail convex groove (13) is connected to the lower surface of the contact block (14); a tension spring (22) is connected between the guide sliding block (16) and the detection clamping block A (20).

4. The detection structure applied to the transfer component of the capacitor laminator according to claim 3, wherein: waist-shaped hole (17) have been seted up to U-shaped guide frame upper surface middle part one side near contact piece (14), the upper surface of contact piece (14) with one side that waist-shaped hole (17) correspond is provided with prevents slow-witted protruding grain (18).

5. The detection structure applied to the transfer component of the capacitor laminator according to claim 4, wherein: the two opposite sides of the inverted U-shaped guide frame (19) in the length direction are connected with the detection clamping block A (20) through bolts (15).

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