CN215438474U - Feeding device for bimetallic strip of temperature controller - Google Patents

Abstract

The utility model discloses a loading device for a bimetallic strip of a temperature controller, which comprises a seventh driving mechanism, a first aligning mechanism and a fourth vibrating disk, wherein the fourth vibrating disk is used for conveying a workpiece, the seventh driving mechanism can move the workpiece to the first aligning mechanism, the first aligning mechanism can align the workpiece, the seventh driving mechanism can move the aligned workpiece to a jig, and the loading device can move the workpieces such as the bimetallic strip and the like to the jig of the first rotating disk, so that automatic loading is realized, and the working efficiency is improved.

Description

Feeding device for bimetallic strip of temperature controller

Technical Field

The utility model relates to the technical field of feeding devices, in particular to a feeding device for a temperature controller bimetallic strip.

Background

The temperature controller is formed by drain pan subassembly, fixed bolster, guide plate, pottery stick, bimetallic strip and upper cover assembly, and every spare part need be in proper order place and assemble on predetermineeing the station, and current equipment process carries out the material loading operation for the form of manual work or semi-automatic assembly line, and production efficiency is lower, and consumes the manpower.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide the loading device for the bimetallic strip of the temperature controller, and the seventh driving mechanism, the first aligning mechanism and the fourth vibrating disc are matched and cooperated to realize automatic loading of the bimetallic strip workpiece, improve the working efficiency and solve the problem of low efficiency of manual or semi-automatic loading operation.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the loading device for the bimetallic strip of the temperature controller comprises a seventh driving mechanism, a first aligning mechanism and a fourth vibrating disk;

the feeding device can move a workpiece to the first rotary table, a plurality of uniformly distributed jigs are arranged at the edge of the first rotary table, and the jigs are provided with circular fixing grooves;

the fourth vibrating disk is used for conveying workpieces;

the seventh driving mechanism can move the workpiece to the first alignment mechanism;

the first aligning mechanism can align the workpiece;

the seventh driving mechanism can move the aligned workpiece to the jig.

From this, this loading attachment can move work pieces such as bimetallic strip to the tool of first carousel in, realizes automatic feeding, improves work efficiency.

In some embodiments, the fourth vibratory pan includes a fourth terminal conveying section, the conveying face of the fourth terminal conveying section being a sloped face;

and a stop block is arranged at the output end of the fourth tail end conveying section.

The inclined transport surface thus promotes a stable transport of the bimetal, the stop serving to define the output position of the bimetal.

In some embodiments, the first alignment mechanism is disposed between the fourth end conveying section and the jig.

In some embodiments, the first alignment mechanism includes a cylinder having an alignment groove formed in a top portion thereof.

Therefore, the bimetallic strip is placed in the aligning groove, and the bimetallic strip can be horizontally placed, so that the bimetallic strip is aligned.

In some embodiments, the seventh drive mechanism includes a fifth vacuum nozzle and a sixth vacuum nozzle;

the fifth vacuum suction nozzle is obliquely arranged and can move the workpiece positioned at the fourth tail end conveying section to the first alignment mechanism;

the sixth vacuum suction nozzle can move the workpiece positioned on the first alignment mechanism to the jig.

Therefore, the inclined fifth vacuum suction nozzle is matched with the inclined conveying surface, the bimetallic strip is convenient to adsorb, and the adjusted bimetallic strip is moved to the jig by the sixth vacuum suction nozzle and assembled on the bottom shell assembly.

In some embodiments, the seventh driving mechanism further comprises a seventh horizontal cylinder, a seventh sliding plate, a seventh vertical cylinder, a seventh slider, an eighth vertical cylinder, and an eighth slider;

the output end of the seventh horizontal cylinder is in driving connection with the seventh sliding plate;

the seventh sliding plate can be horizontally and slidably connected with the fifth base frame;

the seventh sliding block and the eighth sliding block are both connected to the seventh sliding plate in a vertically sliding manner;

the output end of the seventh vertical cylinder is in driving connection with the seventh sliding block;

the output end of the eighth vertical cylinder is in driving connection with the eighth sliding block;

the fifth vacuum suction nozzle is connected with the seventh sliding block;

the sixth vacuum suction nozzle is connected to the eighth slider.

From this, the seventh slider and the eighth slider are all connected in the seventh slide, realize synchronous horizontal motion under the drive of seventh slide, seventh vertical cylinder and eighth vertical cylinder independent drive seventh slider and eighth slider vertical motion respectively, and fifth vacuum suction nozzle adsorbs and moves the bimetallic strip to the alignment groove of first alignment mechanism, and then sixth vacuum suction nozzle adsorbs and moves the bimetallic strip after adjusting to the tool again to assemble in drain pan subassembly.

In some embodiments, the fifth base frame is provided with a fifth limit screw.

From this, the top of fifth bed frame is equipped with the diaphragm, and on seventh actuating mechanism located the diaphragm, the diaphragm both ends all were equipped with the curb plate, and the curb plate all is equipped with fifth stop screw for inject actuating mechanism's stroke.

The utility model has the beneficial effects that: and under the cooperation and cooperation of the seventh driving mechanism, the first aligning mechanism and the fourth vibrating disk, the automatic feeding of the bimetallic strip workpiece is realized, and the working efficiency is improved.

Drawings

Fig. 1 is a top view of a loading device for a bimetal of a temperature controller according to the present invention;

fig. 2 is an isometric view of a loading device for a bimetal of a thermostat according to the present invention, in which a fourth vibration plate is omitted;

FIG. 3 is a structural view of a seventh drive mechanism of the present invention;

FIG. 4 is an isometric view of a thermostat of the present invention;

FIG. 5 is an exploded view of the thermostat of the present invention;

wherein: 51-a seventh drive mechanism; 511-a seventh horizontal cylinder; 512-seventh sled; 513-a seventh vertical cylinder; 514-seventh slider; 515-a fifth vacuum nozzle; 516-an eighth vertical cylinder; 517-eighth slider; 518-sixth vacuum nozzle; 52-first alignment mechanism; 521-a cylinder; 5211-alignment groove; 53-a fifth base frame; 531-fifth stop screw; 54-a fourth vibratory pan; 541-a fourth end conveying section; 5411-transport surface; 542-a stopper; 100-a first carousel; 110-a jig; 110 a-a fixed slot; 300-temperature controller; 310-a bottom shell assembly; 320-a fixed bracket; 330-a guide vane; 340-a ceramic rod; 350-bimetallic strip; 360-upper cover.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 to 5, the loading device for the bimetallic strip of the thermostat includes a seventh driving mechanism 51, a first aligning mechanism 52 and a fourth vibrating plate 54;

the feeding device can move a workpiece to the first rotating disc 100, a plurality of uniformly distributed jigs 110 are arranged at the edge part of the first rotating disc 100, and the jigs 110 are provided with circular fixing grooves 110 a;

the fourth vibratory pan 54 is used for conveying the workpiece;

the seventh driving mechanism 51 is capable of moving the workpiece to the first alignment mechanism 52;

the first alignment mechanism 52 can align the workpiece;

the seventh driving mechanism 51 can move the aligned workpiece to the jig 110.

The temperature controller 300 is assembled by a bottom shell assembly 310, a fixing bracket 320, a guide plate 330, a ceramic rod 340, a bimetal 350 and an upper cover 360, and the feeding device is used for moving workpieces such as the bimetal 350 to the first rotating disc 100 and assembling the workpieces in the bottom shell assembly 310, so that automatic feeding and assembling are realized, and the working efficiency is improved.

After the ceramic rod 340 of the temperature controller 300 is assembled to the bottom case assembly 310, the bottom case assembly 310 is placed on the fixing groove 110a of the fixture 110, the first rotating disc 100 is driven by the corresponding motor to rotate and is transferred to the loading station of the bimetal 350, and then the loading device loads the bimetal 350 and assembles the bimetal 350 to the bottom case assembly 310, i.e., above the guiding plate 330.

The bimetallic strip 350 is conveyed under the vibration of the fourth vibration disc 54, the seventh driving mechanism 51 moves the bimetallic strip 350 to the first aligning mechanism 52, the first aligning mechanism 52 horizontally aligns the inclined workpiece of the bimetallic strip 350, the seventh driving mechanism 51 moves the aligned bimetallic strip 350 to the bottom shell assembly 310 in the jig 110, and the bimetallic strip 350 is assembled to the bottom shell assembly 310, so that the automatic feeding of the bimetallic strip 350 is realized, and the working efficiency is improved.

Further, the fourth vibration tray 54 includes a fourth end conveying section 541, and a conveying surface 5411 of the fourth end conveying section 541 is an inclined surface;

the output end of the fourth end conveying section 541 is provided with a stopper 542.

The inclined delivery surface 5411 facilitates stable delivery of the bimetal 350, and the stopper 542 serves to define the output position of the bimetal 350.

Further, the first alignment mechanism 52 is disposed between the fourth end conveying section 541 and the fixture 110.

Further, the first alignment mechanism 52 includes a cylinder 521, and an alignment groove 5211 is formed at the top of the cylinder 521. The bimetal 350 is placed in the aligning groove 5211, so that the bimetal 350 can be horizontally placed, and thus, aligned.

To explain further, an infrared detector may be disposed below the alignment groove 5211 to detect whether the bimetal 350 is in place.

Further illustrating, the seventh driving mechanism 51 comprises a fifth vacuum suction nozzle 515 and a sixth vacuum suction nozzle 518;

the fifth vacuum suction nozzle 515 is arranged obliquely, and the fifth vacuum suction nozzle 515 can move the workpiece positioned at the fourth end conveying section 541 to the first alignment mechanism 52;

the sixth vacuum nozzle 518 is capable of moving the workpiece positioned in the first alignment mechanism 52 to the fixture 110.

The inclined fifth vacuum suction nozzle 515 is matched with the inclined conveying surface 5411 so as to absorb the bimetal 350, and the sixth vacuum suction nozzle 518 moves the aligned bimetal 350 to the jig 110 and assembles the adjusted bimetal 350 to the bottom shell assembly 310.

To explain further, the seventh driving mechanism 51 further includes a seventh horizontal cylinder 511, a seventh sliding plate 512, a seventh vertical cylinder 513, a seventh sliding block 514, an eighth vertical cylinder 516 and an eighth sliding block 517;

the output end of the seventh horizontal cylinder 511 is in driving connection with the seventh sliding plate 512;

the seventh sliding plate 512 is connected to the fifth base frame 53 in a horizontally slidable manner;

the seventh sliding block 514 and the eighth sliding block 517 are both connected to the seventh sliding plate 512 in a vertically sliding manner;

the output end of the seventh vertical cylinder 513 is in driving connection with the seventh sliding block 514;

the output end of the eighth vertical cylinder 516 is in driving connection with the eighth sliding block 517;

the fifth vacuum suction nozzle 515 is connected to the seventh slider 514;

the sixth vacuum nozzle 518 is connected to an eighth slider 517.

The seventh sliding block 514 and the eighth sliding block 517 are both connected to the seventh sliding plate 512, and are driven by the seventh sliding plate 512 to perform synchronous horizontal movement, the seventh vertical cylinder 513 and the eighth vertical cylinder 516 respectively and independently drive the seventh sliding block 514 and the eighth sliding block 517 to perform vertical movement, the fifth vacuum nozzle 515 adsorbs and moves the bimetal 350 to the alignment groove 5211 of the first alignment mechanism 52, and then the sixth vacuum nozzle 518 adsorbs and moves the aligned bimetal 350 to the jig 110, and is assembled on the bottom case assembly 310.

Because the fifth vacuum nozzle 515 and the sixth vacuum nozzle 518 are in synchronous horizontal movement, the distances between the output end of the fourth end delivery section 541, the alignment groove 5211 and the fixture 110 are equal to the distance between the two vacuum nozzles.

To explain further, the fifth base frame 53 is provided with a fifth limit screw 531.

The top of the fifth base frame 53 is provided with a transverse plate, the seventh driving mechanism 51 is arranged on the transverse plate, two ends of the transverse plate are provided with side plates, and the side plates are provided with fifth limiting screws 531 for limiting the stroke of the seventh driving mechanism 51.

The foregoing disclosure discloses only some embodiments of the utility model. It will be apparent to those skilled in the art that various changes and modifications can be made without departing from the inventive concept herein, and it is intended to cover all such modifications and variations as fall within the scope of the utility model.

Claims (7)

1. The loading device for the bimetallic strip of the temperature controller is characterized by comprising a seventh driving mechanism (51), a first aligning mechanism (52) and a fourth vibrating disc (54);

the feeding device can move a workpiece to a first rotating disc (100), a plurality of uniformly distributed jigs (110) are arranged at the edge part of the first rotating disc (100), and circular fixing grooves (110a) are formed in the jigs (110);

the fourth vibrating disc (54) is used for conveying workpieces;

-said seventh driving means (51) being able to move the workpiece to said first alignment means (52);

the first alignment mechanism (52) can align a workpiece;

the seventh driving mechanism (51) can move the aligned workpiece to the jig (110).

2. The loading device of the thermostat bimetal of claim 1, wherein the fourth vibration plate (54) comprises a fourth terminal conveying section (541), and a conveying surface (5411) of the fourth terminal conveying section (541) is an inclined surface;

and a stop block (542) is arranged at the output end of the fourth tail end conveying section (541).

3. The loading device for the bimetallic strip of the temperature controller according to claim 2, wherein the first alignment mechanism (52) is disposed between the fourth end conveying section (541) and the fixture (110).

4. The loading device of the thermostat bimetal of claim 3, wherein the first alignment mechanism (52) comprises a cylinder (521), and an alignment groove (5211) is formed at the top of the cylinder (521).

5. The loading device of the thermostat bimetal of claim 4, wherein the seventh driving mechanism (51) comprises a fifth vacuum suction nozzle (515) and a sixth vacuum suction nozzle (518);

the fifth vacuum suction nozzle (515) is obliquely arranged, and the fifth vacuum suction nozzle (515) can move the workpiece positioned at the fourth tail end conveying section (541) to the first alignment mechanism (52);

the sixth vacuum suction nozzle (518) is capable of moving the workpiece positioned at the first alignment mechanism (52) to the jig (110).

6. The loading device of the thermostat bimetallic strip according to claim 5, characterized in that the seventh driving mechanism (51) further comprises a seventh horizontal cylinder (511), a seventh sliding plate (512), a seventh vertical cylinder (513), a seventh sliding block (514), an eighth vertical cylinder (516) and an eighth sliding block (517);

the output end of the seventh horizontal cylinder (511) is in driving connection with the seventh sliding plate (512);

the seventh sliding plate (512) is connected to the fifth base frame (53) in a horizontally sliding manner;

the seventh sliding block (514) and the eighth sliding block (517) are both connected to the seventh sliding plate (512) in a vertically sliding manner;

the output end of the seventh vertical cylinder (513) is in driving connection with the seventh sliding block (514);

the output end of the eighth vertical cylinder (516) is in driving connection with the eighth sliding block (517);

said fifth vacuum nozzle (515) being connected to said seventh slider (514);

the sixth vacuum nozzle (518) is connected to the eighth slider (517).

7. A loading device for bimetal of thermostat according to claim 6, characterised in that the fifth base frame (53) is provided with a fifth limit screw (531).

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