CN116929948A - Silicon carbide honeycomb ceramic strength performance detection device and detection method thereof - Google Patents
Silicon carbide honeycomb ceramic strength performance detection device and detection method thereof Download PDFInfo
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- CN116929948A CN116929948A CN202311189623.3A CN202311189623A CN116929948A CN 116929948 A CN116929948 A CN 116929948A CN 202311189623 A CN202311189623 A CN 202311189623A CN 116929948 A CN116929948 A CN 116929948A
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- 238000001514 detection method Methods 0.000 title claims abstract description 76
- 229910010271 silicon carbide Inorganic materials 0.000 title claims abstract description 59
- 239000000919 ceramic Substances 0.000 title claims abstract description 58
- HBMJWWWQQXIZIP-UHFFFAOYSA-N silicon carbide Chemical compound [Si+]#[C-] HBMJWWWQQXIZIP-UHFFFAOYSA-N 0.000 title claims abstract description 57
- 238000004140 cleaning Methods 0.000 claims abstract description 33
- 238000000034 method Methods 0.000 claims abstract description 30
- 230000005540 biological transmission Effects 0.000 claims abstract description 14
- 239000000463 material Substances 0.000 claims description 10
- 238000003860 storage Methods 0.000 claims description 10
- 238000003825 pressing Methods 0.000 claims description 4
- 230000000694 effects Effects 0.000 claims description 3
- 239000012634 fragment Substances 0.000 description 10
- 230000001681 protective effect Effects 0.000 description 4
- 238000010586 diagram Methods 0.000 description 3
- 230000003014 reinforcing effect Effects 0.000 description 3
- 229910010293 ceramic material Inorganic materials 0.000 description 2
- 230000003647 oxidation Effects 0.000 description 2
- 238000007254 oxidation reaction Methods 0.000 description 2
- 230000002093 peripheral effect Effects 0.000 description 2
- 238000005299 abrasion Methods 0.000 description 1
- 230000004075 alteration Effects 0.000 description 1
- 230000001174 ascending effect Effects 0.000 description 1
- 238000005452 bending Methods 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000008602 contraction Effects 0.000 description 1
- 238000005260 corrosion Methods 0.000 description 1
- 230000007797 corrosion Effects 0.000 description 1
- 238000004519 manufacturing process Methods 0.000 description 1
- 238000004377 microelectronic Methods 0.000 description 1
- 238000005065 mining Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 229910052575 non-oxide ceramic Inorganic materials 0.000 description 1
- 239000011225 non-oxide ceramic Substances 0.000 description 1
- 239000003921 oil Substances 0.000 description 1
- 238000005457 optimization Methods 0.000 description 1
- 239000003208 petroleum Substances 0.000 description 1
- 239000000126 substance Substances 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N3/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N3/08—Investigating strength properties of solid materials by application of mechanical stress by applying steady tensile or compressive forces
- G01N3/10—Investigating strength properties of solid materials by application of mechanical stress by applying steady tensile or compressive forces generated by pneumatic or hydraulic pressure
- G01N3/12—Pressure testing
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N3/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N3/02—Details
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/0014—Type of force applied
- G01N2203/0016—Tensile or compressive
- G01N2203/0019—Compressive
-
- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N2203/00—Investigating strength properties of solid materials by application of mechanical stress
- G01N2203/003—Generation of the force
- G01N2203/0042—Pneumatic or hydraulic means
- G01N2203/0048—Hydraulic means
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Abstract
The invention belongs to the technical field of detection of silicon carbide honeycomb ceramics and discloses a device and a method for detecting the strength performance of the silicon carbide honeycomb ceramics, wherein the device comprises a shell, a workbench is fixedly arranged in the shell, a detection block is movably arranged above the workbench, a movable driving component for driving the detection block to move up and down is fixedly arranged on the inner top wall of the shell, four centering rods are slidably arranged on the upper surface of the workbench, driving components for driving the four centering rods to move towards or away from each other are fixedly arranged on the lower surface of the workbench, a cleaning component is slidably arranged on the upper surface of the workbench, and a transmission component is arranged between the cleaning component and the movable driving component.
Description
Technical Field
The invention belongs to the technical field of detection of silicon carbide honeycomb ceramics, and particularly relates to a device and a method for detecting strength performance of silicon carbide honeycomb ceramics.
Background
Silicon carbide honeycomb ceramics are widely used in the fields of petroleum, chemical industry, microelectronics, automobiles, aerospace, aviation, papermaking, laser, mining industry, atomic energy and other industries.
The silicon carbide honeycomb ceramic is a honeycomb ceramic with silicon carbide as a main component; the silicon carbide honeycomb ceramics not only have excellent normal temperature mechanical properties, such as higher bending strength, excellent oxidation resistance, good corrosion resistance and higher abrasion resistance, but also have the best high temperature mechanical properties (strength, creep resistance and the like) among the known ceramic materials; the high-temperature strength can be maintained to 1600 ℃ all the time, and the ceramic material is the material with the best high-temperature strength; oxidation resistance is also the best of all non-oxide ceramics.
In the prior art, in order to guarantee product quality, the intensity of the silicon carbide honeycomb ceramic needs to be sampled and detected after the production of the silicon carbide honeycomb ceramic is finished, when the intensity of the silicon carbide honeycomb ceramic is detected, the intensity detection device needs to be used for detecting, the existing intensity detection device is single in function, broken fragments in the detection process need to be cleaned manually, the workload of workers is increased, the position of the detected silicon carbide honeycomb ceramic needs to be adjusted manually, if the pressing position is not the center of the silicon carbide honeycomb ceramic, the stress of the silicon carbide honeycomb ceramic is easily caused to deviate, and the accuracy of the detection result is influenced.
Disclosure of Invention
The invention aims to solve the technical problem of providing the silicon carbide honeycomb ceramic strength performance detection device and the detection method thereof, which can automatically align the silicon carbide honeycomb ceramic to be detected, enable the silicon carbide honeycomb ceramic to be positioned at a detection station, improve the accuracy of detection results, automatically clean broken fragments in the detection process, facilitate the use and improve the use effect.
In order to solve the technical problems, the invention provides the following technical scheme:
the utility model provides a carborundum honeycomb pottery intensity performance detection device, which comprises an outer shell, fixed mounting has the workstation in the shell, workstation top activity is provided with the detection piece, fixed mounting has the removal drive assembly that is used for driving the detection piece and reciprocates on the inner roof of shell, slidable mounting has four centering bars on the upper surface of workstation, fixed mounting has the drive assembly that is used for driving four centering bars to being close to each other or keeping away from each other the orientation removal on the lower surface of workstation, slidable mounting has the subassembly that cleans on the upper surface of workstation, be provided with transmission subassembly between cleaning assembly and the removal drive assembly.
The following is a further optimization of the above technical solution according to the present invention:
the movable driving assembly comprises a plurality of hydraulic telescopic rods fixedly mounted on the inner top wall of the shell, the telescopic ends of the hydraulic telescopic rods are vertically downwards distributed, the end parts of the hydraulic telescopic rods are fixedly connected with mounting plates, and the detection blocks are fixedly mounted on the lower surfaces of the mounting plates.
Further optimizing: the workbench is characterized in that long holes are respectively formed in positions, corresponding to the four centering rods, of the workbench, the four long holes are distributed in a radial mode, the top ends of the centering rods are located above the workbench, and the bottom ends of the centering rods penetrate through the long holes and extend to the lower side of the workbench.
Further optimizing: the driving assembly comprises a fixed box fixedly arranged on the lower surface of the workbench, a motor is fixedly arranged on the inner top wall of the fixed box, a screw rod is connected to the bottom end part of the centering rod through threads, and one end of the screw rod, which is close to the fixed box, penetrates through the fixed box and is in transmission connection with the power output end of the motor.
Further optimizing: four guide rods are fixedly connected to the outer surface of the fixed box, the other ends of the guide rods penetrate through corresponding centering rods and are fixedly connected with second limiting blocks, and the guide rods are in sliding connection with the centering rods.
Further optimizing: the cleaning assembly comprises a movable rod arranged above the workbench, the movable rod is connected to the inner wall of the shell in a sliding manner, a cleaning brush is arranged on the lower side of the movable rod, two sliding rods are fixedly connected to the upper surface of the cleaning brush, and the top ends of the sliding rods penetrate through the movable rod and are fixedly connected with a fixed block; the outer surface of the sliding rod is sleeved with a spring, and two ends of the spring are fixedly connected with the corresponding movable rod and the cleaning brush respectively.
Further optimizing: the transmission assembly comprises a first rotating shaft arranged on one side of the movable rod, one end part of the first rotating shaft is rotationally connected with the inner wall of the shell through a bearing, the other end of the first rotating shaft is fixedly provided with a disc, the movable rod is hinged with a connecting rod through a pin shaft, and the other end of the connecting rod is rotationally connected to the front face of the disc and is close to the edge position through the pin shaft.
Further optimizing: the inner wall of the shell is rotatably provided with a second rotating shaft, the outer surface of the second rotating shaft is fixedly provided with a first belt wheel, the outer surface of the second rotating shaft is rotatably connected with a gear through a one-way bearing, the gear is meshed with a rack, the bottom end of the rack is fixedly connected with a mounting plate, the outer surface of the first rotating shaft is fixedly connected with a second belt wheel, and the first belt wheel is connected with the second belt wheel through belt transmission.
Further optimizing: a material leakage opening is formed in the position, close to the right side, of the workbench; a storage box is arranged in the shell and below the material leakage opening;
and a pressure sensor is arranged on the inner side surface of the top end of the centering rod.
The invention also provides a detection method of the silicon carbide honeycomb ceramic strength performance detection device, which is based on the silicon carbide honeycomb ceramic strength performance detection device and comprises the following steps:
step one, placing circular silicon carbide honeycomb ceramics to be detected on a workbench, starting a motor to drive four screw rods to rotate, driving corresponding centering rods to move towards the middle part in the rotating process of the screw rods, pushing the silicon carbide honeycomb ceramics to the position right below a detection block, and reversing the motor to reset the four centering rods;
step two, starting the hydraulic telescopic rod to extend and driving the mounting plate and the detection block to move downwards, and pressing the silicon carbide honeycomb ceramic for pressure detection after the detection block moves downwards;
step three, the hydraulic telescopic rod contracts and drives the mounting plate and the detection block to move upwards after detection is completed, the mounting plate drives the rack to move in the moving process, the rack and the gear are meshed to drive the second rotating shaft and the first belt wheel to rotate, the first belt wheel drives the second belt wheel, the first rotating shaft and the disc to rotate through the belt, and at the moment, the disc drives the movable rod and the cleaning brush to reciprocate through the connecting rod in the rotating process.
Compared with the prior art, the invention has the following beneficial effects:
1. the motor works, four centering rods are driven by four screw rods to move towards the middle part and push the silicon carbide honeycomb ceramic to the position right below the detection block, so that the position of the silicon carbide honeycomb ceramic can be automatically adjusted, the silicon carbide honeycomb ceramic is positioned at the central position of the detection station, the phenomenon that stress is offset due to the position offset of the silicon carbide honeycomb ceramic is avoided, and the accuracy of a detection result is improved.
2. The hydraulic telescopic rod works to enable the telescopic end of the hydraulic telescopic rod to extend or retract, when the telescopic end of the hydraulic telescopic rod extends, the mounting plate and the detection block can be driven to move downwards, the detection block is propped against the silicon carbide honeycomb ceramic to be detected, and pressure detection is carried out on the silicon carbide honeycomb ceramic.
3. When the flexible end of hydraulic telescoping rod is retracted, can drive mounting panel and detection piece and upwards remove, can drive through drive assembly and clean the subassembly and remove this moment, clean the subassembly and remove and can carry out automatic clearance to the fragment that produces on the workstation after detecting, make the fragment fall into the storage box through the feed opening and store, reduce staff's work load, reduce workman intensity of labour, improve result of use.
The invention will be further described with reference to the drawings and examples.
Drawings
FIG. 1 is a schematic perspective view of an embodiment of the present invention;
FIG. 2 is a schematic view of the structure of the inside of the housing according to the embodiment of the present invention;
FIG. 3 is a top cross-sectional view of the overall structure of an embodiment of the present invention;
FIG. 4 is a schematic diagram of a driving assembly according to an embodiment of the present invention;
FIG. 5 is a cross-sectional view of a drive assembly according to an embodiment of the present invention;
FIG. 6 is a schematic view of a cleaning assembly according to an embodiment of the present invention;
FIG. 7 is a schematic diagram of a transmission assembly according to an embodiment of the present invention;
FIG. 8 is a schematic diagram of a control system according to an embodiment of the invention.
In the figure: 1-a housing; 2-a hydraulic telescopic rod; 3-a detection block; 4-mounting plates; 5-a workbench; 6-a drive assembly; 7-centering the rod; 8-a pressure sensor; 9-a material leakage port; 10-a movable rod; 11-a cleaning assembly; 12-a first rotating shaft; 13-a disc; 14-connecting rods; 15-a storage box; 16-a guide rail; 17-a slider; 101-a first guard door; 102-a second guard gate; 601-a fixed box; 602-long holes; 603-a motor; 604-a first bevel gear; 605-a second bevel gear; 606-screw rod; 607-a first stopper; 608—a guide bar; 609-a second stopper; 1101-cleaning brush; 1102-a slide bar; 1103-fixed block; 1104-a spring; 18-a second rotating shaft; 19-a first pulley; 20-gear; 21-a rack; 22-a second pulley; 23-a belt; 24-reinforcing bars.
Detailed Description
As shown in figures 1-8, the silicon carbide honeycomb ceramic strength performance detection device comprises a shell 1, a workbench 5 is fixedly installed in the shell 1, a detection block 3 is movably arranged above the workbench 5, a movable driving component for driving the detection block 3 to move up and down is fixedly installed on the inner top wall of the shell 1, four centering rods 7 are slidably installed on the upper surface of the workbench 5, a driving component 6 for driving the four centering rods 7 to move towards or away from each other is fixedly installed on the lower surface of the workbench 5, a cleaning component 11 is slidably installed on the upper surface of the workbench 5, and a transmission component is arranged between the cleaning component 11 and the movable driving component.
As shown in fig. 1 and fig. 2, in this embodiment, openings are respectively formed on the upper and lower sides of the front surface of the housing 1, and a first protection door 101 and a second protection door 102 are respectively installed on the two openings, where the first protection door 101 and the second protection door 102 are respectively located on the upper and lower sides of the workbench 5.
By the design, the cavity above the workbench 5 in the shell 1 can be opened or closed through the first protective door 101, and the first protective door 101 is closed in the detection process, so that workers can be protected, broken fragments are prevented from splashing, and safety is improved; the chamber below the workbench 5 in the housing 1 can be opened or closed by the second protective door 102, so that the use is convenient.
The movable driving assembly comprises a plurality of hydraulic telescopic rods 2 fixedly installed on the inner top wall of the shell 1, the hydraulic telescopic rods 2 are distributed at intervals, the telescopic ends of the hydraulic telescopic rods 2 are vertically and downwards distributed, the telescopic ends of the hydraulic telescopic rods 2 are fixedly connected with a mounting plate 4, and the detection blocks 3 are fixedly installed on the lower surface of the mounting plate 4.
The hydraulic telescopic rod 2 works to enable the telescopic end of the hydraulic telescopic rod to extend or retract, at the moment, the telescopic end of the hydraulic telescopic rod 2 can drive the mounting plate 4 to lift and move, and the mounting plate 4 moves to drive the detection block 3 to move.
The positions of the workbench 5 corresponding to the four centering rods 7 are respectively provided with long holes 602, the four long holes 602 are distributed radially, the top ends of the centering rods 7 are positioned above the workbench 5, and the bottom ends of the centering rods 7 penetrate through the long holes 602 and extend to the lower side of the workbench 5.
The centering rods 7 are respectively and slidably mounted in the corresponding long holes 602, and the centering rods 7 can slide along the corresponding long holes 602, so that the use is convenient.
The driving assembly 6 comprises a fixing box 601 fixedly installed on the lower surface of the workbench 5, a motor 603 is fixedly installed on the inner top wall of the fixing box 601, screw rods 606 are connected to the bottom end parts of the centering rods 7 in a threaded mode, and the screw rods 606 are vertically distributed with the centering rods 7.
One end of the screw rod 606, which is close to the fixed box 601, penetrates through the fixed box 601 and is in transmission connection with the power output end of the motor 603.
A first limiting block 607 is fixedly arranged on one end part of the screw rod 606 far from the fixing box 601, and the first limiting block 607 is used for limiting the position of the centering rod 7 on the screw rod 606.
The connection part of the screw rod 606 and the fixed box 601 is provided with a bearing, the screw rod 606 is rotationally connected with the fixed box 601 through the bearing, and the screw rod 606 is in threaded connection with the centering rod 7.
As shown in fig. 2, 4 and 5, in this embodiment, a first bevel gear 604 is fixedly connected to the power output end of the motor 603, and a second bevel gear 605 is fixedly mounted on one end of the screw rod 606 located in the fixing box 601, and the second bevel gears 605 are respectively engaged with the first bevel gears 604.
In such design, the starting motor 603 drives the first bevel gear 604 to rotate, the first bevel gear 604 is matched with the four second bevel gears 605 in the rotating process to drive the screw rod 606 to rotate, and because the screw rod 606 is in threaded connection with the centering rod 7, the four screw rods 606 can drive the four centering rods 7 to move towards the middle part in the rotating process and push the silicon carbide honeycomb ceramic to the position right below the detection block 3, so that the silicon carbide honeycomb ceramic to be detected is automatically aligned, and the use is convenient.
As shown in fig. 4 and 5, in this embodiment, four guide rods 608 are fixedly connected to the outer surface of the fixing case 601, and the other ends of the guide rods 608 respectively penetrate through the corresponding centering rods 7 and are fixedly connected to second limiting blocks 609, and the guide rods 608 are slidably connected to the centering rods 7.
By means of the design, the guide rod 608 is in sliding connection with the centering rod 7, the guide rod 608 can guide movement of the centering rod 7, and further the centering rod 7 is more stable when moving, and the phenomenon that the centering rod 7 rotates along with the screw rod 606 is avoided.
The cleaning assembly 11 comprises a movable rod 10 arranged above the workbench 5, the movable rod 10 is slidably connected to the inner wall of the shell 1, a cleaning brush 1101 is arranged on the lower side of the movable rod 10, a sliding rod 1102 is fixedly connected to the upper surface of the cleaning brush 1101 and near the two ends of the cleaning brush 1101 respectively, and the top end of the sliding rod 1102 penetrates through the movable rod 10 and is fixedly connected with a fixing block 1103.
In this embodiment, the sliding rod 1102 is slidably connected to the movable rod 10.
The outer surface of the sliding rod 1102 is sleeved with a spring 1104, the upper end of the spring 1104 is fixedly connected with the movable rod 10, and the lower end of the spring 1104 is fixedly connected with the upper surface of the sliding rod 1102.
In this way, the spring 1104 outputs an elastic force to the cleaning brush 1101, and the cleaning brush 1101 drives the sliding rod 1102 to slide downwards, so that the cleaning brush 1101 is better attached to the upper surface of the workbench 5.
A guide rail 16 is fixedly arranged on the inner wall of the shell 1 and positioned on one side of the movable rod 10, a sliding block 17 is connected to the guide rail 16 in a sliding manner, and one side of the movable rod 10, which is close to the sliding block 17, is fixedly connected with the sliding block 17.
The transmission assembly comprises a first rotating shaft 12 arranged on one side of the movable rod 10, one end of the first rotating shaft 12 is rotatably connected with the inner wall of the shell 1 through a bearing, and a disc 13 is fixedly arranged at the other end of the first rotating shaft 12.
The movable rod 10 is rotatably connected with a connecting rod 14 through a pin shaft, and the other end of the connecting rod 14 is rotatably connected to the front surface of the disc 13 and near the edge position through the pin shaft.
By means of the design, the disc 13 can drive the connecting rod 14 to move in the rotating process, when the disc 13 drives the connecting rod 14 to rotate to the upper half circle, the connecting rod 14 drives the movable rod 10 to move rightwards along the guide rail 16, and the movable rod 10 can drive the cleaning brush 1101 to move rightwards in the moving process and push detected fragments to the right side.
When the disc 13 drives the connecting rod 14 to rotate to the lower half circle, the connecting rod 14 drives the movable rod 10 to move leftwards along the guide rail 16, and the movable rod 10 can drive the cleaning assembly 11 to reset leftwards in the moving process.
The inner wall of the shell 1 is rotatably provided with a second rotating shaft 18, the outer surface of the second rotating shaft 18 is fixedly provided with a first belt pulley 19, the outer surface of the second rotating shaft 18 is rotatably connected with a gear 20 through a one-way bearing, the gear 20 is in meshed connection with a rack 21, and the bottom end of the rack 21 is fixedly connected with the mounting plate 4.
The outer surface of the first rotating shaft 12 is fixedly connected with a second belt wheel 22, and the first belt wheel 19 is in transmission connection with the second belt wheel 22 through a belt 23.
When the telescopic end of the hydraulic telescopic rod 2 stretches, the telescopic end of the hydraulic telescopic rod 2 drives the mounting plate 4 and the detection block 3 to move downwards, and the gear 20 rotates relative to the second rotating shaft 18 when the mounting plate 4 drives the rack 21 to move downwards at the moment because the gear 20 is connected with the second rotating shaft 18 in a rotating way through the one-way bearing, and then the gear 20 does not drive the second rotating shaft 18 to rotate.
When the telescopic end of the hydraulic telescopic rod 2 contracts, the telescopic end of the hydraulic telescopic rod 2 drives the mounting plate 4 and the detection block 3 to move upwards, the mounting plate 4 can drive the rack 21 to move in the moving process, the rack 21 is meshed with the gear 20 in the moving process to drive the second rotating shaft 18 and the first belt wheel 19 to rotate, and the first belt wheel 19 drives the second belt wheel 22, the first rotating shaft 12 and the disc 13 to rotate through the belt 23 in the rotating process.
As shown in fig. 7, in this embodiment, a reinforcing rod 24 is fixedly connected to one side of the rack 21, and a bottom end of the reinforcing rod 24 is fixedly connected to the mounting plate 4.
By means of the design, the joint of the rack 21 and the mounting plate 4 can be supported and reinforced through the reinforcing rod 24, so that the rack 21 is more firmly mounted, and falling is avoided.
As shown in fig. 1 and 2, in this embodiment, a material leakage opening 9 is formed on the working table 5 near the right side thereof; a storage box 15 is arranged in the shell 1 and below the material leakage opening 9; fragments discharged from the material leakage opening 9 fall into the material storage box 15 for storage.
A pressure sensor 8 is arranged on the inner side surface of the top end of the centering rod 7.
The outside of shell 1 is provided with the peripheral hardware switch board, be provided with control system in the peripheral hardware switch board, the output of pressure sensor 8 and control system's input electric connection.
As shown in fig. 1-8, the control system includes a main controller, an output end of the pressure sensor 8 is electrically connected with an input end of the main controller, and the input end of the main controller is electrically connected with a start button, an emergency stop button, a push button and an up button.
The control end of the motor 603 is electrically connected with a forward and reverse rotation driving unit, and the forward and reverse rotation driving unit is used for enabling the motor 603 to perform forward rotation or reverse rotation.
The oil inlet and outlet of the hydraulic telescopic rod 2 is communicated with an external hydraulic pump station through a control pipeline, an electromagnetic valve is arranged on the control pipeline, and the electromagnetic valve on the control pipeline is used for controlling the telescopic end of the hydraulic telescopic rod 2 to extend or retract.
The output end of the main controller is electrically connected with the forward and reverse rotation driving unit and the control end of the control pipeline, and the main controller sends out a control signal for controlling the motor 603 and the hydraulic telescopic rod 2 to work.
In this embodiment, a pressure preset threshold is set in the main controller, and the pressure sensor 8 is configured to detect a real-time pressure between the centering rod 7 and the silicon carbide honeycomb ceramic, and send the real-time pressure signal to the main controller, where the main controller compares the real-time pressure with the pressure preset threshold.
When the silicon carbide honeycomb ceramic detection block is used, the starting button is pressed down, at the moment, the main controller sends a control signal to enable the motor 603 to rotate positively through the positive and negative rotation driving unit, at the moment, the motor 603 outputs rotation power to drive the four screw rods 606 to rotate, and the screw rods 606 can drive the corresponding centering rod 7 to move towards the middle part and push the silicon carbide honeycomb ceramic to the position right below the detection block 3 in the rotating process.
The pressure sensor 8 is used for detecting the real-time pressure between the centering rod 7 and the silicon carbide honeycomb ceramic and sending the real-time pressure signal into the main controller, and the main controller compares the real-time pressure with a pressure preset threshold value.
When the real-time pressure is greater than the pressure preset threshold, the main controller sends out a control signal to enable the motor 603 to reverse through the forward and reverse driving unit, and at the moment, the four centering rods 7 are automatically reset.
In this embodiment, the main controller is in the prior art, and the forward and reverse driving unit and the control pipeline are in the prior art.
In this embodiment, the main controller sends a control signal to extend the hydraulic telescopic rod 2 through the control pipeline by pressing the push button; and when the ascending button is pressed, the main controller sends out a control signal to enable the hydraulic telescopic rod 2 to perform contraction action through the control pipeline.
As shown in fig. 1-8, the invention further provides a detection method of the silicon carbide honeycomb ceramic strength performance detection device, based on the silicon carbide honeycomb ceramic strength performance detection device, the detection method comprises the following steps:
step one, placing round silicon carbide honeycomb ceramics to be detected on a workbench 5, closing a first protective door 101, then starting a motor 603 to drive four screw rods 606 to rotate, enabling the screw rods 606 to drive corresponding centering rods 7 to move towards the middle in the rotating process and pushing the silicon carbide honeycomb ceramics to the position right below a detection block 3, then enabling a pressure sensor 8 to detect real-time pressure between the centering rods 7 and the silicon carbide honeycomb ceramics and sending the real-time pressure signal into a main controller, and controlling the motor 603 to rotate reversely according to the real-time pressure signal, wherein the four centering rods 7 are automatically reset.
In the first step, the motor 603 is used to drive the first bevel gear 604 to rotate, and the first bevel gear 604 cooperates with the four second bevel gears 605 to drive the screw rod 606 to rotate in the rotating process, and the screw rod 606 is in threaded connection with the centering rod 7, so that the screw rod 606 can drive the four centering rods 7 to move towards the middle in the rotating process and push the silicon carbide honeycomb ceramic to the position right below the detection block 3.
Step two, the hydraulic telescopic rod 2 is started to extend and drive the mounting plate 4 and the detection block 3 to move downwards, and because the gear 20 is rotationally connected with the second rotating shaft 18 through the one-way bearing, the gear 20 can not be driven to rotate the second rotating shaft 18 by the gear 20 after the mounting plate 4 drives the rack 21 to move downwards, and the pressure detection is carried out on the silicon carbide honeycomb ceramics after the detection block 3 moves downwards.
Step three, after the detection is completed, the hydraulic telescopic rod 2 contracts and drives the mounting plate 4 and the detection block 3 to move upwards, the mounting plate 4 can drive the rack 21 to move in the moving process, the rack 21 is meshed with the gear 20 and can drive the second rotating shaft 18 and the first belt wheel 19 to rotate, the first belt wheel 19 drives the second belt wheel 22, the first rotating shaft 12 and the disc 13 to rotate through the belt 23 in the rotating process, and at the moment, the disc 13 drives the movable rod 10 and the cleaning brush 1101 to reciprocate through the connecting rod 14 in the rotating process.
In the third step, the disc 13 drives the movable rod 10 and the cleaning brush 1101 to reciprocate once through the connecting rod 14, and when the disc 13 drives the connecting rod 14 to rotate for the upper half circle, the connecting rod 14 drives the movable rod 10 to move rightward along the guide rail 16, and the movable rod 10 can drive the cleaning brush 1101 to move rightward and push the detected fragments to the right side in the moving process; at this point the pieces are discharged through the weep 9 and fall into the magazine 15 for storage.
When the disc 13 drives the connecting rod 14 to rotate to the lower half circle, the connecting rod 14 drives the movable rod 10 to move leftwards along the guide rail 16, and the movable rod 10 can drive the cleaning assembly 11 to move leftwards and reset in the moving process.
After the storage box 15 is fully filled with fragments, the second protection door 102 is opened to clean out the fragments in the storage box 15.
Alterations, modifications, substitutions and variations of the embodiments herein will be apparent to those of ordinary skill in the art in light of the teachings of the present invention without departing from the spirit and principles of the invention.
Claims (10)
1. The utility model provides a carborundum honeycomb ceramic intensity performance detection device which characterized in that: including shell (1), fixed mounting has workstation (5) in shell (1), workstation (5) top activity is provided with detects piece (3), fixed mounting has the removal drive assembly that is used for driving to detect piece (3) reciprocate on the interior roof of shell (1), slidable mounting has four centering bars (7) on the upper surface of workstation (5), fixed mounting has drive assembly (6) that are used for driving four centering bars (7) to be close to each other or keep away from each other the direction removal on the lower surface of workstation (5), slidable mounting has cleaning assembly (11) on the upper surface of workstation (5), be provided with transmission subassembly between cleaning assembly (11) and the removal drive assembly.
2. The silicon carbide honeycomb ceramic strength performance detection device according to claim 1, wherein: the movable driving assembly comprises a plurality of hydraulic telescopic rods (2) fixedly installed on the inner top wall of the shell (1), the telescopic ends of the hydraulic telescopic rods (2) are vertically and downwards distributed, the end parts of the hydraulic telescopic rods are fixedly connected with mounting plates (4), and the detection blocks (3) are fixedly installed on the lower surfaces of the mounting plates (4).
3. The silicon carbide honeycomb ceramic strength performance detection device according to claim 2, wherein: the workbench (5) is provided with long holes (602) at positions corresponding to the four centering rods (7), the four long holes (602) are distributed radially, the top end of the centering rod (7) is located above the workbench (5), and the bottom end of the centering rod (7) penetrates through the long holes (602) and extends to the lower side of the workbench (5).
4. A silicon carbide honeycomb ceramic strength property detection apparatus according to claim 3, wherein: the driving assembly (6) comprises a fixing box (601) fixedly installed on the lower surface of the workbench (5), a motor (603) is fixedly installed on the inner top wall of the fixing box (601), a screw rod (606) is connected to the bottom end portion of the centering rod (7) in a threaded mode, and one end, close to the fixing box (601), of the screw rod (606) penetrates through the fixing box (601) and is in transmission connection with the power output end of the motor (603).
5. The silicon carbide honeycomb ceramic strength performance detection device according to claim 4, wherein: four guide rods (608) are fixedly connected to the outer surface of the fixed box (601), the other ends of the guide rods (608) penetrate through corresponding centering rods (7) and are fixedly connected with second limiting blocks (609), and the guide rods (608) are in sliding connection with the centering rods (7).
6. The silicon carbide honeycomb ceramic strength performance detection device according to claim 5, wherein: the cleaning assembly (11) comprises a movable rod (10) arranged above the workbench (5), the movable rod (10) is connected to the inner wall of the shell (1) in a sliding mode, a cleaning brush (1101) is arranged on the lower side of the movable rod (10), two sliding rods (1102) are fixedly connected to the upper surface of the cleaning brush (1101), and the top ends of the sliding rods (1102) penetrate through the movable rod (10) and are fixedly connected with a fixed block (1103); the outer surface of the sliding rod (1102) is sleeved with a spring (1104), and two ends of the spring (1104) are fixedly connected with the corresponding movable rod (10) and the cleaning brush (1101) respectively.
7. The silicon carbide honeycomb ceramic strength property detection device according to claim 6, wherein: the transmission assembly comprises a first rotating shaft (12) arranged on one side of a movable rod (10), one end part of the first rotating shaft (12) is rotatably connected with the inner wall of the shell (1) through a bearing, a disc (13) is fixedly arranged at the other end of the first rotating shaft (12), a connecting rod (14) is hinged to the movable rod (10) through a pin shaft, and the other end of the connecting rod (14) is rotatably connected to the front surface of the disc (13) and is close to the edge position through the pin shaft.
8. The silicon carbide honeycomb ceramic strength property detection device according to claim 7, wherein: the inner wall of the shell (1) is rotatably provided with a second rotating shaft (18), the outer surface of the second rotating shaft (18) is fixedly provided with a first belt wheel (19), the outer surface of the second rotating shaft (18) is rotatably connected with a gear (20) through a one-way bearing, the gear (20) is meshed and connected with a rack (21), the bottom end of the rack (21) is fixedly connected with a mounting plate (4), the outer surface of the first rotating shaft (12) is fixedly connected with a second belt wheel (22), and the first belt wheel (19) is in transmission connection with the second belt wheel (22) through a belt (23).
9. The silicon carbide honeycomb ceramic strength property detection device according to claim 8, wherein: a material leakage opening (9) is formed in the position, close to the right side, of the workbench (5); a storage box (15) is arranged in the shell (1) and below the material leakage opening (9);
a pressure sensor (8) is arranged on the inner side surface of the top end of the centering rod (7).
10. A method for detecting a strength performance detecting device of silicon carbide honeycomb ceramics, based on the strength performance detecting device of the silicon carbide honeycomb ceramics according to the claim 9, characterized in that: the method comprises the following steps:
firstly, placing circular silicon carbide honeycomb ceramics to be detected on a workbench (5), starting a motor (603) to drive four screw rods (606) to rotate, driving corresponding centering rods (7) to move towards the middle part in the rotating process of the screw rods (606) and pushing the silicon carbide honeycomb ceramics to the position right below a detection block (3), and then reversing the motor (603) to reset the four centering rods (7);
step two, starting the hydraulic telescopic rod (2) to extend and driving the mounting plate (4) and the detection block (3) to move downwards, and pressing the silicon carbide honeycomb ceramic for pressure detection after the detection block (3) moves downwards;
step three, after the detection is completed, the hydraulic telescopic rod (2) contracts and drives the mounting plate (4) and the detection block (3) to move upwards, the mounting plate (4) drives the rack (21) to move in the moving process, the rack (21) is meshed with the gear (20) to drive the second rotating shaft (18) and the first belt wheel (19) to rotate, the first belt wheel (19) drives the second belt wheel (22), the first rotating shaft (12) and the disc (13) to rotate through the belt (23), and at the moment, the disc (13) drives the movable rod (10) and the cleaning brush (1101) to move reciprocally through the connecting rod (14) in the rotating process.
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