CN200986511Y - Full-automatic metallurgy ball compression testing machine - Google Patents

Abstract

The utility model discloses a fully-automatic metallurgical pellet compressing tester, which includes a main frame, an upper beam, two screws arranged between the main frame and the upper beam, a cross beam movable up and down along the screw, an upper press head arranged under the movable cross beam, a lower press plate arranged on the main frame and fitted with the upper press head, and a feeding device to feed a test part to the space between the upper press head and the lower press plate. The feeding device includes a feeding mechanism arranged on the main frame and a conveying mechanism connected with the feeding mechanism through a conveying pipe. The utility model prevents the cases of that a plurality of test balls block the conveying pipe or a pushing plate, and that a plurality of test balls drop into the pushing plate simultaneously, and improves operation stability of the tester and reliability of the test results.

Description

Full-automatic metallurgical briquetting compression testing machine

Technical field

The utility model relates to compression testing machine, relates in particular to a kind of full-automatic metallurgical briquetting compression testing machine.

Background technology

Existing metallurgical briquetting compression testing machine comprises as shown in Figure 1 to Figure 3: hopper 5, force transducer 4, seaming chuck 13, push pedal actuator 8, sliding platform 10, fuselage 9, push pedal 11, the lower platen 12 of entablature 1, screw mandrel 2, moving beam 3, loading sample.During work, push pedal actuator 8 drives push pedals 11 motions, and when the feed opening in the push pedal 11 alignd with the blanking port of hopper 5, test ball 14 can drop in the feed opening in the push pedal 11 because of gravitational effect.Because there is individual difference in test ball 14, may differ in size, different.Fall in the feed opening in the push pedal 11 so a plurality of test balls 14 might occur, it is inaccurate or block the phenomenon of push pedal this moment to occur test findings.

The utility model content

The purpose of this utility model is in order to solve above-mentioned problems of the prior art, a kind of full-automatic metallurgical briquetting compression testing machine to be provided.

For addressing the above problem, the technical scheme that the utility model proposes is: a kind of full-automatic metallurgical briquetting compression testing machine, comprise: fuselage, entablature, two screw mandrels that are arranged between fuselage and the entablature, the moving beam that moves up and down along described screw mandrel, be arranged on the seaming chuck of described moving beam below, be arranged on the lower platen that cooperates with described seaming chuck on the described fuselage, and test specimen delivered to pay-off between seaming chuck and the lower platen, wherein: described pay-off comprises feeding mechanism that is arranged on the fuselage and the feed mechanism that is connected with feeding mechanism by delivery pipe.

Described feeding mechanism comprises push pedal and makes push pedal come and go the actuator that moves;

Described feed mechanism comprise the vibrating bunker support that is used for fixing vibrating bunker, by solenoid actuated have spiral material road vibrating bunker, be located at the optoelectronic switch of the control charging of material road outlet.

Compared with prior art, during the work of the testing machine that the utility model proposes, the test ball in the vibrating bunker rises along the slippage of spiral material road, the test ball can pile-up together.Simultaneously, quit work after the each work of vibrating bunker falls one to testing ball, therefore, do not have the phenomenon that a plurality of test balls block conveying pipeline or push pedal at once, or the phenomenon that a plurality of test balls fall in the push pedal simultaneously occurs, and improved the stability of testing machine work and the reliability of test findings.

Description of drawings

Below in conjunction with drawings and Examples the utility model is described further, wherein:

Fig. 1 is the schematic perspective view of prior art testing machine;

Fig. 2 is the side sectional view of testing machine shown in Figure 1;

Fig. 3 is the enlarged diagram of A portion among Fig. 2;

Fig. 4 is a schematic perspective view of the present utility model;

Fig. 5 looks cut-open view for a left side of the present utility model;

Fig. 6 is that cut-open view is looked on the right side of the present utility model;

Fig. 7 is the enlarged diagram of A portion among Fig. 6.

Embodiment

Extremely shown in Figure 7 as Fig. 4, the utility model comprises: fuselage 9, entablature 1, two screw mandrels 2 that are arranged between fuselage and the entablature, along the moving beam 3 that described screw mandrel moves up and down, the moving beam below is provided with force transducer 4, is arranged on the seaming chuck 13 of described moving beam below, be arranged on the lower platen 12 that cooperates with described seaming chuck 13 on the described fuselage, and test specimen is delivered to pay-off between seaming chuck and the lower platen.Wherein: described pay-off comprises feeding mechanism that is arranged on the fuselage and the feed mechanism that is connected with feeding mechanism by delivery pipe 6.Feeding mechanism comprises push pedal 11 and makes push pedal come and go the actuator 8 that moves; Feed mechanism comprises the vibrating bunker support 7 that is used for fixing vibrating bunker, is had the vibrating bunker 5 in spiral material road and be located at the optoelectronic switch 15 of the control charging of material road outlet by solenoid actuated.

Before the work of this testing machine, the operator puts into vibrating bunker 5 to test ball 14 earlier.

When beginning to test, be installed in the vibrating bunker 5 energising work on the vibrating bunker support 7, test ball 14 will rise along the spiral material road slippage in the vibrating bunker 5.As a test ball 14 when falling into feed opening, triggering is installed in optoelectronic switch 15 on the vibrating bunker 5.At this moment, vibrating bunker 5 outages quit work, and test ball 14 stops the slippage rising in the vibrating bunker 5.

The following test ball 14 that falls behind slides in the push pedal along conveying pipeline 6.Then, push pedal actuator 8 drives push pedal 11 motions.When the feed opening in the push pedal 11 alignd with the blanking port of conveying pipeline 6, test ball 14 can be because gravitational effect drops in the feed opening in the push pedal 11.Afterwards, push pedal actuator 8 drives push pedal 11 motions.When the feed opening in the push pedal 11 and seaming chuck are on same axial line, push pedal 11 stop motions.

The machine operation that is installed in the fuselage 9 drives screw mandrel 2 rotations, and screw mandrel 2 rotates drive moving beams 3 and moves downward.Until till being installed in seaming chuck 13 on the moving beam 3 the test balls 14 in the push pedal 11 being crushed.

Screw mandrel 2 rotates drive moving beam 3 and moves upward, and turns back to initial position and stops.Then, push pedal actuator 8 drives push pedal 11 motions, until push pedal 8 stops after test ball 14 waste materials after crushing are pushed away lower platen 12.Testing machine is finished a test circulation.

The utility model work the time phenomenon that a plurality of test balls 14 block conveying pipeline or push pedal can not occur, or a plurality of test ball falls into the phenomenon in the push pedal simultaneously, has improved the stability of testing machine work and the reliability of test findings.

Above-mentioned cited embodiment is only in order to illustrate the utility model, is not in order to limiting scope of the present utility model, those of ordinary skill in the art in not breaking away from spirit and scope of the present utility model, modifications and changes according to demand.Yet this conversion and modification all belong within the scope of the utility model claim protection.

Claims (5)

1, a kind of full-automatic metallurgical briquetting compression testing machine, comprise: fuselage, entablature, two screw mandrels that are arranged between fuselage and the entablature, the moving beam that moves up and down along described screw mandrel, be arranged on the seaming chuck of described moving beam below, be arranged on the lower platen that cooperates with described seaming chuck on the described fuselage, and test specimen delivered to pay-off between seaming chuck and the lower platen, it is characterized in that: described pay-off comprises feeding mechanism that is arranged on the fuselage and the feed mechanism that is connected with feeding mechanism by delivery pipe.

2, full-automatic metallurgical briquetting compression testing machine according to claim 1 is characterized in that: described feeding mechanism comprises push pedal and makes push pedal come and go the actuator that moves.

3, full-automatic metallurgical briquetting compression testing machine according to claim 1 is characterized in that: described feed mechanism comprise the vibrating bunker support that is used for fixing vibrating bunker, by solenoid actuated have spiral material road vibrating bunker, be located at the optoelectronic switch of the control charging of material road outlet.

4, full-automatic metallurgical briquetting compression testing machine according to claim 2 is characterized in that: described delivery pipe road junction is provided with the optoelectronic switch of control charging.

5, full-automatic metallurgical briquetting compression testing machine according to claim 1 is characterized in that: described moving beam below is provided with force transducer.

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