CN219168977U - Carbon anode detection device - Google Patents

Abstract

The utility model relates to a carbon anode detection device in the technical field of carbon electrode detection equipment, which comprises a conveyor, wherein a detection assembly and a material rejecting assembly are sequentially arranged on the conveyor along the conveying direction; the detection assembly comprises a first bracket and a detector, the detector is fixed right above the conveying surface of the conveyor, and the detector is electrically connected with the picking assembly; the picking assembly comprises a second support, a rotating arm and a clamping piece, the second support is fixedly connected with the frame of the conveyor, the rotating arm is arranged at the top end of the second support, one end of the rotating arm extends to the position right above the conveying surface of the conveyor and is connected with the clamping piece, and the picking assembly is matched with the transferring assembly. The detector is matched with the picking assembly, unqualified products can be timely picked up and transported away, the detection continuity is high, the efficiency is high, the detection effect is good, the production efficiency is improved, and the production is facilitated.

Description

Carbon anode detection device

Technical Field

The utility model belongs to the technical field of carbon electrode detection equipment, and particularly relates to a carbon anode detection device.

Background

In the production process of anode carbon blocks, detection of finished carbon blocks is an important part, in order to ensure quality of the anode carbon blocks, detection is needed, and patent number CN211651552U discloses an anode carbon block height measuring device, which comprises a mounting base plate, a sliding rail is fixed on the mounting base plate, a sliding table is connected onto the sliding rail in a sliding manner, a driving structure for driving the sliding table to move is further fixed on the mounting base plate, a roller frame is fixed on the sliding table, a plurality of rotating rollers are connected into the roller frame, a cylinder frame is further fixed on the mounting base plate, a measuring cylinder is fixed on the cylinder frame, a long hole is formed in a cylinder rod of the measuring cylinder, and a distance sensor is fixed on the bottom of the measuring cylinder. This patent judges through measuring the removal of cylinder that the charcoal piece is high whether qualified, and when rejecting unqualified product, needs manual handling, and overall detection process continuity is poor, has reduced production efficiency, consequently, needs a carbon anode detection device to solve above-mentioned problem.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model provides a carbon anode detection device which comprises a conveyor, wherein a detection assembly and a picking assembly are sequentially arranged on the conveyor along the conveying direction;

the detection assembly comprises a first bracket and a detector, wherein the first bracket is fixed on a rack of the conveyor, the detector is fixedly connected with the first bracket, the detector is fixed right above a conveying surface of the conveyor, and the detector is electrically connected with the picking assembly;

the material picking assembly comprises a second support, a rotating arm and a clamping piece, wherein the second support is fixedly connected with the frame of the conveyor, the rotating arm is arranged at the top end of the second support, one end of the rotating arm extends to the position right above the conveying surface of the conveyor and is connected with the clamping piece, and the material picking assembly is matched with the transferring assembly.

Preferably, the transfer assembly is a belt conveyor.

Preferably, the conveyor is a belt conveyor.

Preferably, the detector is an infrared range finder. The infrared range finder is the prior art, and the connection and control of the infrared range finder and the controller are all common technical means in the field, and are not repeated here

Preferably, the rotating arm comprises a forward and reverse rotating motor and a horizontal rod, wherein the forward and reverse rotating motor is fixed at the top end of the second bracket, and an output shaft of the forward and reverse rotating motor is fixedly connected with one end of the horizontal rod.

Preferably, the clamping piece comprises a vertical telescopic rod and a finger cylinder, wherein the fixed end of the vertical telescopic rod is fixedly connected with the horizontal rod at one end far away from the forward and reverse rotating motor, the telescopic end of the vertical telescopic rod is vertically downward and fixedly connected with the finger cylinder, and the clamping jaw of the finger cylinder is matched with the carbon anode.

Preferably, the vertical telescopic rod is an electric push rod or an air cylinder or a hydraulic cylinder.

The utility model further comprises a control system, wherein the detector, the forward and reverse rotating motor, the conveyor, the vertical telescopic rod and the clamping piece are all connected with the control system, the control system can be a PLC controller, and the connection and the control are all in the prior art and are not repeated.

The utility model also comprises other components which can enable the carbon anode detection device to be normally used, for example, a control component of a positive and negative rotation motor, a control component of a detector, a control component of a vertical telescopic rod, a control component of a conveyor, a control component of a belt conveyor, a control component of a finger cylinder and the like are all conventional technical means in the field. In addition, the undefined devices or components in the utility model all adopt the conventional technical means in the field, such as finger cylinder, electric push rod, infrared range finder, belt conveyor and the like, which are conventional devices in the field.

The working principle of the utility model is as follows: the carbon anodes are sequentially placed on a conveying belt of the conveyor and are sequentially conveyed to the lower part of the detector along the conveying direction, the detector detects the distance from the detection head to the upper part of the carbon anodes, so that whether the height of the carbon anodes meets the requirements is judged, and if the height meets the requirements, the carbon anodes are conveyed away by the conveyor; if the requirements are not met, when the vertical telescopic rod stretches to the clamping piece, the clamping piece is driven to move downwards to clamp the unqualified carbon anode, the vertical telescopic rod contracts, the forward and backward rotating motor rotates, the horizontal rod rotates to the upper side of the transferring assembly with the clamped unqualified carbon anode, the vertical telescopic rod stretches again to match with the clamping piece to place the unqualified carbon anode on the transferring assembly to be transferred away, the clamping piece is treated additionally, then the clamping piece resets to wait for the next transfer, the conveyor does not stop conveying when the clamping piece transfers the unqualified carbon anode, and the detector also keeps continuous work, so that the detection efficiency is improved, and the production is facilitated.

The utility model has the beneficial effects that the detector is matched with the picking assembly, unqualified products can be timely picked up and transported away, the detection continuity is high, the efficiency is high, the detection effect is good, the production efficiency is improved, and the production is facilitated.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic diagram of a carbon anode detection device according to an embodiment of the present utility model;

FIG. 2 is a left side view of FIG. 1;

FIG. 3 is a top view of FIG. 1;

fig. 4 is a state diagram of the transfer assembly of fig. 3 transferring a failed carbon anode.

In the figure: 1. a conveyor; 2. a first bracket; 3. a detector; 4. a clamping jaw; 5. a vertical telescopic rod; 6. a horizontal bar; 7. a forward and reverse rotation motor; 8. a second bracket; 9. a carbon anode; 10. and a transfer assembly.

Detailed Description

The present utility model will now be described more fully hereinafter with reference to the accompanying drawings, in which embodiments of the utility model are shown, and in which embodiments of the utility model are shown. All other embodiments, modifications, equivalents, improvements, etc., which are apparent to those skilled in the art without the benefit of this disclosure, are intended to be included within the scope of this utility model.

Examples

As shown in fig. 1-4, the utility model provides a carbon anode detection device, which comprises a conveyor 1, wherein a detection assembly and a picking assembly are sequentially arranged on the conveyor 1 along the conveying direction;

the detection assembly comprises a first bracket 2 and a detector 3, the first bracket 2 is fixed on a rack of the conveyor 1, the detector 3 is fixedly connected with the first bracket 2, the detector 3 is fixed right above a conveying surface of the conveyor 1, the detector 3 is electrically connected with the picking assembly, and the detector 3 is an infrared range finder;

the material picking assembly comprises a second bracket 8, a rotating arm and a clamping piece, wherein the second bracket 8 is fixedly connected with a frame of the conveyor 1, the rotating arm is arranged at the top end of the second bracket 8 and comprises a forward and reverse motor 7 and a horizontal rod 6, the forward and reverse motor 7 is fixed at the top end of the second bracket 8, an output shaft of the forward and reverse motor 7 is fixedly connected with one end of the horizontal rod 6, the other end of the horizontal rod 6 extends to the position right above a conveying surface of the conveyor 1 and is connected with the clamping piece, the clamping piece comprises a vertical telescopic rod 5 and a finger cylinder, the fixed end of the vertical telescopic rod 5 is fixedly connected with one end of the horizontal rod 6 far away from the forward and reverse motor 7, the telescopic end of the vertical telescopic rod 5 is vertically downwards and fixedly connected with the finger cylinder, the vertical telescopic rod 5 is an electric push rod, and a clamping jaw 4 of the finger cylinder is matched with a carbon anode 9; the material picking assembly is matched with a transferring assembly 10, and the transferring assembly 10 is a belt conveyor.

The conveyor 1 is also a belt conveyor.

The utility model further comprises a control system, wherein the detector, the forward and reverse rotation motor, the conveyor, the electric push rod and the finger cylinder are all connected with the control system, the control system is a PLC controller, and the connection and the control are all in the prior art and are not repeated.

When the device works, the carbon anodes 9 are sequentially placed on the conveying belt of the conveyor 1 and are sequentially conveyed to the lower part of the detector 3 along the conveying direction, the detector 3 detects the distance from the detection head to the upper part of the carbon anodes 9, so that whether the height of the carbon anodes 9 meets the requirement is judged, and if the height meets the requirement, the carbon anodes are conveyed away by the conveyor 1; if the requirements are not met, when the vertical telescopic rod 5 stretches to the clamping piece, the finger cylinder is driven to move downwards, the clamping jaw 4 clamps the unqualified carbon anode 9, the vertical telescopic rod 5 contracts, the forward and backward rotating motor 7 rotates, the horizontal rod 6 rotates to the upper part of the transferring assembly 10 with the clamped unqualified carbon anode, the vertical telescopic rod stretches again to match with the clamping piece to place the unqualified carbon anode 9 on the transferring assembly 10 to be transferred away, the clamping piece is reset and waits for the next transfer, the conveyor does not stop conveying when the clamping piece transfers the unqualified carbon anode, the detector also keeps continuous work, the detection efficiency is improved, and the production is facilitated.

The embodiments of the present utility model have been described above, the description is illustrative, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (7)

1. The utility model provides a carbon anode detection device, includes conveyer, its characterized in that: the conveyor is sequentially provided with a detection assembly and a picking assembly along the conveying direction;

the detection assembly comprises a first bracket and a detector, wherein the first bracket is fixed on a rack of the conveyor, the detector is fixedly connected with the first bracket, the detector is fixed right above a conveying surface of the conveyor, and the detector is electrically connected with the picking assembly;

the material picking assembly comprises a second support, a rotating arm and a clamping piece, wherein the second support is fixedly connected with the frame of the conveyor, the rotating arm is arranged at the top end of the second support, one end of the rotating arm extends to the position right above the conveying surface of the conveyor and is connected with the clamping piece, and the material picking assembly is matched with the transferring assembly.

2. The carbon anode detection device according to claim 1, wherein: the transfer assembly is a belt conveyor.

3. The carbon anode detection device according to claim 1, wherein: the conveyor is a belt conveyor.

4. The carbon anode detection device according to claim 1, wherein: the detector is an infrared range finder.

5. The carbon anode detection device according to claim 1, wherein: the rotating arm comprises a forward and reverse rotating motor and a horizontal rod, wherein the forward and reverse rotating motor is fixed at the top end of the second bracket, and an output shaft of the forward and reverse rotating motor is fixedly connected with one end of the horizontal rod.

6. The carbon anode detection device according to claim 5, wherein: the clamping piece comprises a vertical telescopic rod and a finger cylinder, wherein the fixed end of the vertical telescopic rod is fixedly connected with the horizontal rod at one end far away from the forward and reverse rotating motor, the telescopic end of the vertical telescopic rod is vertically downward and fixedly connected with the finger cylinder, and the clamping jaw of the finger cylinder is matched with the carbon anode.

7. The carbon anode detection device according to claim 6, wherein: the vertical telescopic rod is an electric push rod or an air cylinder or a hydraulic cylinder.

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