CN219625386U - Quality inspection device is used in graphite crucible production - Google Patents

Abstract

The utility model discloses a quality inspection device for graphite crucible production, which comprises: the device comprises a concave conveyor, a set monitoring box and a pair of conveying pushing supports, wherein the set monitoring box is sleeved on the concave conveyor, the pair of conveying pushing supports are installed on the concave conveyor, a quantitative pushing structure is installed on the pair of conveying pushing supports and the set monitoring box, and a lifting monitoring structure is installed on the set monitoring box; the utility model relates to the technical field of graphite crucible production, wherein dyes are led to the inner side of a graphite crucible, liquid is evaporated by heating, so that the dyes are remained between gaps of the graphite crucible, whether the gaps appear in the graphite crucible can be rapidly judged by different colors, and partial dyes can be remained between the gaps by the principle of thermal expansion and cold contraction.

Description

Quality inspection device is used in graphite crucible production

Technical Field

The utility model relates to the technical field of graphite crucible production, in particular to a quality inspection device for graphite crucible production.

Background

Graphite crucibles, also known as copper clad and copper clad, are a type of crucible that is fired from graphite, clay, silica and pyrophyllite as raw materials. The graphite crucible is mainly used for smelting non-ferrous metals such as red copper, brass, gold, silver, zinc, lead and the like and alloys thereof, is processed by taking natural crystalline flake graphite as a main raw material and taking plastic refractory clay or carbon as a binder, and has the characteristics of high temperature resistance, strong heat conduction performance, good corrosion resistance, long service life and the like. In the high-temperature use process, the thermal expansion coefficient is small, and the alloy has certain strain resistance to quenching and rapid heating. Has strong corrosion resistance to acidic and alkaline solutions, excellent chemical stability and no participation in any chemical reaction in the smelting process. The inner wall of the graphite crucible is smooth, and molten metal liquid is not easy to leak and adhere to the inner wall of the crucible, so that the metal liquid has good fluidity and casting property, and is suitable for casting and forming of various different moulds. Because the graphite crucible has the excellent characteristics, the graphite crucible is widely used for smelting alloy tool steel and nonferrous metals and alloys thereof, but the conventional graphite crucible inspection device cannot effectively inspect the alloy tool steel in the aspect of bearing force and is easy to damage in the process of detection.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a quality inspection device for graphite crucible production, which solves the problems of the prior art.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: a quality inspection device for graphite crucible production includes: the device comprises a concave conveyor, a set monitoring box and a pair of conveying pushing supports, wherein the set monitoring box is sleeved on the concave conveyor, the pair of conveying pushing supports are installed on the concave conveyor, a quantitative pushing structure is installed on the pair of conveying pushing supports and the set monitoring box, and a lifting monitoring structure is installed on the set monitoring box;

the lifting monitoring structure comprises: the device comprises a concave lifting block, a lifting monitoring plate, two pairs of lifting monitoring hydraulic push rods, a coiled inductor, a metal heating rod, a drainage feeding pipe, a feeding pump and a detection raw material box; the device comprises a circular ring exhaust pipe, a plurality of exhaust drainage pipes, an exhaust pump and a lifting detection camera;

the device comprises a lifting monitoring box, a lifting monitoring plate, a drainage feeding pipe, a detection raw material box, a feeding pump, a lifting detection camera and a winding inductor, wherein the lifting monitoring box is arranged on the inner side of the lifting monitoring box in a parallel mode, the lifting monitoring plate is arranged on the pushing end of the lifting monitoring box, the drainage feeding pipe is inserted on the lifting monitoring plate, the detection raw material box is arranged on the lifting monitoring plate, the feeding pump is arranged on the detection raw material box, the feeding pump is connected on the drainage feeding pipe, the lifting monitoring plate is arranged on the lifting monitoring block in a parallel mode, the winding inductor is inserted on the lifting block in a concave mode, the metal heating rod is inserted on the lifting block in a circular ring, the circular ring air suction pipe is arranged on the lifting block, and a plurality of air suction drainage pipes are uniformly inserted on the circular ring air suction pipe and the lifting monitoring block.

Preferably, the quantitative pushing structure comprises: the device comprises a pair of concave telescopic limiting brackets, a plurality of extrusion telescopic hydraulic push rods, a pair of concave horizontal pushing blocks, a pair of convex horizontal pushing blocks, a pair of wave extrusion blocks and a pair of horizontal pushing hydraulic push rods;

the device comprises a pair of concave telescopic limit brackets, a pair of telescopic monitoring boxes, a pair of conveying push brackets, a plurality of extrusion telescopic hydraulic push rods, a pair of concave horizontal push blocks, a pair of convex horizontal push blocks, a pair of wave extrusion blocks and a pair of horizontal push hydraulic push rods, wherein the concave telescopic limit brackets are respectively installed on the set monitoring boxes and the pair of conveying push brackets, the extrusion telescopic hydraulic push rods are respectively installed on the pair of concave telescopic limit brackets, the pair of concave horizontal push blocks are respectively movably inserted on the inner sides of the pair of concave telescopic limit brackets, the pair of concave horizontal push blocks are respectively connected to the pushing ends of the extrusion telescopic hydraulic push rods, the pair of convex horizontal push blocks are respectively movably inserted on the pair of concave horizontal push blocks, the pair of wave extrusion blocks are respectively installed on the pair of convex horizontal push blocks, and the pushing ends of the horizontal push hydraulic push rods are respectively connected to the pair of convex horizontal push blocks.

Preferably, a pair of the concave horizontal pushing blocks and a pair of the convex horizontal pushing blocks are respectively provided with a plurality of ball grooves, and the inner sides of the ball grooves are respectively provided with a movable ball.

Preferably, a color liquid is arranged in the detection raw material box.

Preferably, a flow sensor is arranged on the drainage feeding pipe.

Preferably, the suction pump is provided with a filter box, and the inner side of the filter box is arranged on the filter cotton.

The utility model provides a quality inspection device for graphite crucible production. The beneficial effects are as follows: this quality inspection device is used in graphite crucible production is through the inboard with dyestuff drainage to graphite crucible, evaporates liquid through the heating for dyestuff remains between the gap of graphite crucible, through different colours, thereby can be quick judge whether the gap appears in graphite crucible, through the principle of expend with heat and contract with cold, thereby can remain partial dyestuff between the messenger gap _。

Drawings

FIG. 1 is a schematic diagram showing a schematic diagram of a quality inspection apparatus for graphite crucible production in a front view.

FIG. 2 is a schematic side sectional view of a quality inspection device for graphite crucible production according to the present utility model.

Fig. 3 is a partial enlarged view of "a" in fig. 1.

In the figure: 1. a concave conveyor; 2. a set monitoring box; 3. transporting and pushing the bracket; 4. a concave lifting block; 5. lifting the monitoring plate; 6. lifting monitoring hydraulic push rods; 7. a coiled inductor; 8. a metal heating rod; 9. drainage feeding pipe; 10. a feeding pump; 11. detecting a raw material box; 12. a circular ring exhaust pipe; 13. an air extraction drainage tube; 14. an air extracting pump; 15. lifting the detection camera; 16. concave telescopic limit bracket; 17. extruding a telescopic hydraulic push rod; 18. a concave horizontal pushing block; 19. a convex horizontal pushing block; 20. a wave extrusion block; 21. and horizontally pushing the hydraulic push rod.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

As shown in fig. 1-3, the set monitoring box 2 is sleeved on the concave conveyor 1, a pair of conveying pushing brackets 3 are installed on the concave conveyor 1, a pair of conveying pushing brackets 3 and the set monitoring box 2 are provided with quantitative pushing structures, and the set monitoring box 2 is provided with lifting monitoring structures;

specifically, the lift monitoring structure includes: the device comprises a concave lifting block 4, a lifting monitoring plate 5, two pairs of lifting monitoring hydraulic push rods 6, a coiled inductor 7, a metal heating rod 8, a drainage feeding pipe 9, a feeding pump 10 and a detection raw material box 11; the device comprises a circular exhaust pipe 12, a plurality of exhaust drainage pipes 13, an exhaust pump 14 and a lifting detection camera 15;

specifically, two pairs of lift monitoring hydraulic push rods 6 are installed in pairs in parallel on the inner sides of the sleeve monitoring boxes 2, the lift monitoring plates 5 are installed on the pushing ends of the two pairs of lift monitoring hydraulic push rods 6, the drainage feeding pipes 9 are inserted on the lift monitoring plates 5, the detection raw material boxes 11 are installed on the lift monitoring plates 5, the feeding pumps 10 are installed on the detection raw material boxes 11, the feeding pumps 10 are connected to the drainage feeding pipes 9, the concave lifting blocks 4 are installed on the lift monitoring plates 5, the coiled inductors 7 are inserted on the concave lifting blocks 4, the metal heating rods 8 are inserted on the concave lifting blocks 4, the circular ring air extracting pipes 12 are installed on the concave lifting blocks 4, the plurality of drainage pipes 13 are evenly inserted on the circular ring air extracting pipes 12 and the concave lifting blocks 4, and the air extracting pumps 14 are installed on the circular ring air extracting pipes 12 and the detection lifting blocks 15.

In the foregoing, the quantitative feeding structure is used for quantitatively feeding the plurality of graphite crucibles, the two pairs of lifting monitoring hydraulic pushing rods 6 are stretched and contracted to drive the lifting monitoring plates 5 on the pushing ends of the two pairs of lifting monitoring hydraulic pushing rods 6, the drainage feeding pipe 9 on the lifting monitoring plates 5 is firstly inserted into the inner side of the graphite crucible, the raw material on the inner side of the detection raw material box 11 is drained to the drainage feeding pipe 9 through the feeding pump 10, the raw material liquid is drained to the inner side of the graphite crucible through the drainage feeding pipe 9, then the graphite crucible is drained to the inner side of the concave lifting block 4 through the quantitative pushing structure, the metal heating rod 8 on the inner side of the concave lifting block 4 is movably inserted into the inner side of the graphite crucible through the lifting of the concave lifting block 4, the coil type inductor 7 is used for carrying out induction heating on the metal heating rod 8 (the electromagnetic heating device is used in the electromagnetic magnetic generation process, the alternating current of 50HZ/60HZ is converted into direct current voltage, then the direct current voltage is output through a control circuit, the direct current with the conversion frequency of 20-40KHZ is output, the fast moving high-voltage current generates magnetic field and generates heat at high speed in a cable, the surface of the container is cut to alternate magnetic force lines after the cable is contacted with an iron container, alternating current (namely vortex) is generated at the metal part at the bottom of the container, the vortex enables iron atoms at the bottom of the container to move at high speed at random, the atoms collide and rub with each other to generate heat energy, in brief, the principle of electromagnetic induction heating is to achieve the effect of self-heating of a heated object by utilizing the conversion between electricity, magnetism and heat energy, and in the same way, air generated by heating is led to the inner side of the circular ring exhaust pipe 12 through a plurality of exhaust pipes 13, the liquid inside the annular exhaust pipe 12 is drained through the air pump 14, then the heated graphite crucible is drained to the bottom end of the lifting detection camera 15 through the quantitative pushing structure, and partial liquid is evaporated inside a gap of the crucible through heating of liquid pigment inside the raw material box, so that residual dye can appear inside the gap of the part.

As shown in fig. 1-3, the quantitative pushing structure includes: a pair of concave telescopic limit brackets 16, a plurality of extrusion telescopic hydraulic push rods 17, a pair of concave horizontal push blocks 18, a pair of convex horizontal push blocks 19, a pair of wave extrusion blocks 20 and a pair of horizontal push hydraulic push rods

Specifically, a pair of telescopic limit brackets 16 are respectively installed on the suit monitoring box 2 and a pair of the transportation push brackets 3, a plurality of telescopic hydraulic push rods 17 are respectively installed on a pair of telescopic limit brackets 16, a pair of horizontal push blocks 18 are respectively movably inserted on the inner sides of the telescopic limit brackets 16, the pair of horizontal push blocks 18 are respectively connected to the pushing ends of the telescopic hydraulic push rods 17, a pair of horizontal push blocks 19 are respectively movably inserted on the pair of horizontal push blocks 18, a pair of wave extrusion blocks 20 are respectively installed on the pair of horizontal push blocks 19, a pair of horizontal push hydraulic push rods 21 are respectively installed on the pair of horizontal push blocks 18, and the pushing ends of the horizontal push hydraulic push rods 21 are respectively connected to the pair of horizontal push blocks 19.

In the above description, the plurality of extrusion telescopic hydraulic pushing rods 17 on the inner side of the pair of concave telescopic limiting brackets 16 are telescopic, the plurality of extrusion telescopic hydraulic pushing rods 17 are driven to be telescopic relatively, the pair of concave horizontal pushing blocks 18 on the pair of extrusion telescopic hydraulic pushing rods 17 are driven to be telescopic relatively through the plurality of extrusion telescopic hydraulic pushing rods 17, the pair of concave horizontal pushing blocks 18 are driven to be telescopic relatively through the pair of concave telescopic limiting brackets 16, the pair of convex horizontal pushing blocks 19 on the pair of concave horizontal pushing blocks are driven to be telescopic, the pair of convex horizontal pushing blocks 19 drive the pair of wave extrusion blocks 20 on the pair of concave horizontal pushing blocks, the pair of wave extrusion blocks 20 extrude the crucible, the pair of wave extrusion blocks 20 stretch and retract through the pair of horizontal pushing hydraulic pushing rods 21, the pair of convex horizontal pushing blocks 19 stretch horizontally along the pair of concave horizontal pushing blocks 18, and accordingly the pair of crucibles on the inner side of the pair of wave extrusion blocks 20 are pushed one by one.

Preferably, a plurality of ball grooves are respectively formed in the pair of concave horizontal pushing blocks 18 and the pair of convex horizontal pushing blocks 19, and moving balls are respectively arranged on the inner sides of the plurality of ball grooves.

Preferably, a color liquid is provided in the detection raw material tank 11.

As a preferable scheme, a flow sensor is arranged on the drainage feeding pipe 9.

Preferably, the suction pump 14 is provided with a filter box, and the inner side of the filter box is mounted on the filter cotton.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation. The term "comprising" an element defined by the term "comprising" does not exclude the presence of other identical elements in a process, method, article or apparatus that comprises the element.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A quality inspection device for graphite crucible production includes: the device is characterized in that the set monitoring box is sleeved on the concave conveyor, the pair of the transport pushing brackets are arranged on the concave conveyor, the pair of the transport pushing brackets and the set monitoring box are provided with quantitative pushing structures, and the set monitoring box is provided with lifting monitoring structures;

the lifting monitoring structure comprises: the device comprises a concave lifting block, a lifting monitoring plate, two pairs of lifting monitoring hydraulic push rods, a coiled inductor, a metal heating rod, a drainage feeding pipe, a feeding pump, a detection raw material box, a circular ring exhaust pipe, a plurality of exhaust drainage pipes, an exhaust pump and a lifting detection camera;

the device comprises a lifting monitoring box, a lifting monitoring plate, a drainage feeding pipe, a detection raw material box, a feeding pump, a lifting detection camera and a winding inductor, wherein the lifting monitoring box is arranged on the inner side of the lifting monitoring box in a parallel mode, the lifting monitoring plate is arranged on the pushing end of the lifting monitoring box, the drainage feeding pipe is inserted on the lifting monitoring plate, the detection raw material box is arranged on the lifting monitoring plate, the feeding pump is arranged on the detection raw material box, the feeding pump is connected on the drainage feeding pipe, the lifting monitoring plate is arranged on the lifting monitoring block in a parallel mode, the winding inductor is inserted on the lifting block in a concave mode, the metal heating rod is inserted on the lifting block in a circular ring, the circular ring air suction pipe is arranged on the lifting block, and a plurality of air suction drainage pipes are uniformly inserted on the circular ring air suction pipe and the lifting monitoring block.

2. The quality inspection device for graphite crucible production according to claim 1, wherein the quantitative pushing structure comprises: the device comprises a pair of concave telescopic limiting brackets, a plurality of extrusion telescopic hydraulic push rods, a pair of concave horizontal pushing blocks, a pair of convex horizontal pushing blocks, a pair of wave extrusion blocks and a pair of horizontal pushing hydraulic push rods;

the device comprises a pair of concave telescopic limit brackets, a pair of telescopic monitoring boxes, a pair of conveying push brackets, a plurality of extrusion telescopic hydraulic push rods, a pair of concave horizontal push blocks, a pair of convex horizontal push blocks, a pair of wave extrusion blocks and a pair of horizontal push hydraulic push rods, wherein the concave telescopic limit brackets are respectively installed on the set monitoring boxes and the pair of conveying push brackets, the extrusion telescopic hydraulic push rods are respectively installed on the pair of concave telescopic limit brackets, the pair of concave horizontal push blocks are respectively movably inserted on the inner sides of the pair of concave telescopic limit brackets, the pair of concave horizontal push blocks are respectively connected to the pushing ends of the extrusion telescopic hydraulic push rods, the pair of convex horizontal push blocks are respectively movably inserted on the pair of concave horizontal push blocks, the pair of wave extrusion blocks are respectively installed on the pair of convex horizontal push blocks, and the pushing ends of the horizontal push hydraulic push rods are respectively connected to the pair of convex horizontal push blocks.

3. The quality inspection device for graphite crucible production according to claim 2, wherein a pair of the concave horizontal pushing blocks and a pair of the convex horizontal pushing blocks are respectively provided with a plurality of ball grooves, and the inner sides of the ball grooves are respectively provided with a movable ball.

4. The quality inspection device for graphite crucible production according to claim 1, wherein a color liquid is provided in the inspection raw material tank.

5. The quality inspection device for graphite crucible production according to claim 1, wherein a flow sensor is arranged on the drainage feeding pipe.

6. The quality inspection device for graphite crucible production according to claim 1, wherein a filter box is provided on the suction pump, and the inner side of the filter box is mounted on the filter cotton.