CN219957489U - Quality detection device for refractory material - Google Patents

Abstract

The utility model belongs to the field of material detection, in particular to a quality detection device for refractory materials, which aims at the problems that the prior quality detection device is inconvenient to cool refractory materials rapidly in the use process and has low cooling efficiency, so that the quality detection efficiency is reduced.

Description

Quality detection device for refractory material

Technical Field

The utility model relates to the technical field of material detection, in particular to a quality detection device for refractory materials.

Background

The refractoriness is an inorganic nonmetallic material with the refractoriness not lower than 1580 ℃, the refractoriness refers to the refractory cone sample which resists the action of high temperature under the condition of no load, the refractory cone sample is now defined as a material which is allowed to be used in a high-temperature environment by physicochemical properties, the conventional refractoriness detection is generally characterized in that the natural environment of an external refractory material is directly detected, the detection condition is rough, the detection is qualified and the problem occurs in the use process frequently, and therefore, the demand for a quality detection device for refractory material production is growing.

Patent document publication CN109633073a discloses a quality detection device for refractory production, which comprises: the shell, cooling shell and heating shell, the inboard top fixedly connected with motor of shell, the terminal fixedly connected with screw thread axle of motor spindle, screw thread axle outside threaded connection has screw thread axle sleeve, screw thread axle sleeve bottom left side fixedly connected with cap, cap bottom right side fixedly connected with vertical fixed plate that sets up.

However, the above patent document is inconvenient to cool the refractory material rapidly during use, and the cooling efficiency is low, so that the quality detection efficiency is reduced, and for this reason, we propose a quality detection device for refractory material to solve the above problems.

Disclosure of Invention

The utility model aims to solve the defects that in the prior art, a quality detection device for refractory materials is inconvenient to rapidly cool in the use process, and the cooling efficiency is low, so that the quality detection efficiency is reduced.

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

the utility model provides a refractory material quality testing device, which comprises a housin, first spout has been seted up to one side of casing, sliding mounting has the mounting panel in the first spout, the bottom of casing is connected with the cooling shell, the bottom of cooling shell is connected with the heating shell, the internal connection of heating shell has combustor and cooling layer, fixed mounting has the fixed plate in the cooling shell, first through-hole has been seted up on the fixed plate, first through-hole internal rotation installs the sleeve pipe, sheathed tube one end is connected with the cooling shower nozzle, the rotary tank has been seted up to the bottom of mounting panel, be provided with positioning mechanism in the rotary tank, first empty slot has been seted up in the mounting panel, the second through-hole has been seted up on the mounting panel, first pivot has been installed in the downthehole rotation of second, the logical groove has all been seted up to cooling shell and heating shell, be connected with the pneumatic valve on the heating shell, first motor is seted up through welded fixed mounting to the top of casing, first mounting hole has been seted up to the top inner wall of first spout, second screw hole internal thread installs the screw rod, one end and the output shaft of screw rod passes through welded fixed connection.

Preferably, a fourth through hole is formed in the inner wall of the bottom of the second empty groove, the fourth through hole is communicated with the rotary groove, a second rotating shaft is rotatably mounted in the fourth through hole, one end of the second rotating shaft is fixedly connected with the top of the positioning plate through welding, chain wheels are fixedly mounted on the other end of the second rotating shaft and the outer side of the first rotating shaft through welding, and the two chain wheels are meshed with the same chain.

Preferably, the fixed plate is provided with a second mounting hole on one side of the cooling shell, the second mounting hole is communicated with the first empty groove, the same worm is rotatably mounted in the two second mounting holes, a second motor is fixedly mounted on the outer side of the cooling shell, an output shaft of the second motor is fixedly connected with one end of the worm through welding, a first gear and a second gear are respectively sleeved on the outer sides of the worm and the sleeve through welding, and the first gear is meshed with the second gear.

Preferably, a third mounting hole is formed in the inner wall of the top of the first empty groove, the third mounting hole is communicated with the first sliding groove, a rectangular rod is rotatably mounted in the third mounting hole, a worm wheel is fixedly mounted at one end of the rectangular rod through welding and is meshed with the worm, a rectangular hole is formed in the first rotating shaft, and the inner wall of the rectangular hole is slidably connected with the outer side of the rectangular rod.

Preferably, the positioning mechanism comprises a positioning plate, the positioning plate is rotatably arranged in the rotary groove, two symmetrical second sliding grooves are formed in the bottom of the positioning plate, clamping plates are slidably arranged in the two second sliding grooves, a third through hole is formed in the outer side of the positioning plate and is communicated with the two second sliding grooves, first threaded holes are formed in the two clamping plates, the same two-way screw rod is arranged in the two first threaded holes in a threaded mode, and one end of the two-way screw rod is connected with a hand wheel.

In the utility model, the quality detection device for the refractory material has the beneficial effects that:

1. when the second motor is started, the worm drives the first gear to rotate, the first gear drives the second gear to rotate, and the second gear drives the sleeve and the cooling spray head to rotate, so that the cold air is sprayed out of the cold air spray nozzle, and the refractory material is cooled.

2. This scheme is when the worm rotates, and the worm drives the worm wheel and rotates, and the worm wheel drives the rectangle pole and rotates, through the setting of the inner wall sliding connection in rectangle pole and rectangular hole, and the rectangle pole drives first pivot and rotates, and two sprockets pass through chain drive, and the second pivot drives locating plate and refractory material and rotates to can make refractory material even quick cooling, improve refractory material quality detection efficiency.

The utility model can be used for conveniently and rapidly cooling the refractory material, has high cooling efficiency, thereby improving the quality detection efficiency of the refractory material, and has simple structure and convenient use.

Drawings

FIG. 1 is a schematic diagram of a refractory quality inspection device according to the present utility model;

FIG. 2 is an enlarged schematic view of the portion A of FIG. 1 of a refractory quality inspection device according to the present utility model;

FIG. 3 is an enlarged schematic view of the portion B of FIG. 1 of a refractory mass inspection device according to the present utility model;

fig. 4 is an enlarged schematic view of a portion C of fig. 1 of a refractory quality inspection apparatus according to the present utility model.

In the figure: 1. a housing; 2. cooling the shell; 3. heating the shell; 4. a first chute; 5. a mounting plate; 6. a burner; 7. a cooling layer; 8. a fixing plate; 9. a sleeve; 10. cooling the spray head; 11. a first motor; 12. a screw; 13. a rotary groove; 14. a positioning plate; 15. a clamping plate; 16. a two-way screw rod; 17. a second motor; 18. a first gear; 19. a second gear; 20. a worm; 21. a first empty slot; 22. a rectangular bar; 23. a worm wheel; 24. a first rotating shaft; 25. a sprocket; 26. a chain; 27. and a second empty slot.

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.

Example 1

Referring to FIG. 1, a refractory material quality inspection device comprises a housing 1, a first chute 4 is provided on one side of the housing 1, a mounting plate 5 is slidably mounted in the first chute 4, a cooling shell 2 is connected to the bottom of the housing 1, a heating shell 3 is connected to the bottom of the cooling shell 2, a burner 6 and a cooling layer 7 are connected to the inside of the heating shell 3, a fixing plate 8 is fixedly mounted in the cooling shell 2, a first through hole is provided on the fixing plate 8, a sleeve 9 is rotatably mounted in the first through hole, one end of the sleeve 9 is connected with a cooling nozzle 10, a rotary groove 13 is provided at the bottom of the mounting plate 5, a positioning mechanism is provided in the rotary groove 13, a first empty groove 21 is provided in the fixing plate 8, a second empty groove 27 is provided in the mounting plate 5, a second through hole is provided in the mounting plate 5, a first rotating shaft 24 is rotatably mounted in the second through hole, through grooves are provided in both the cooling shell 2 and the heating shell 3, the heating shell 3 is connected with an air valve, the top of the shell 1 is fixedly provided with a first motor 11 through welding, the top inner wall of the first sliding chute 4 is provided with a first mounting hole, the mounting plate 5 is provided with a second threaded hole, the second threaded hole is internally provided with a screw 12, one end of the screw 12 is fixedly connected with the output shaft of the first motor 11 through welding, one sides of the fixing plate 8 and the cooling shell 2 are provided with second mounting holes, the second mounting holes are communicated with a first empty slot 21, the same worm 20 is rotatably arranged in the two second mounting holes, the outer side of the cooling shell 2 is fixedly provided with a second motor 17, the output shaft of the second motor 17 is fixedly connected with one end of the worm 20 through welding, the worm 20 is respectively provided with a first gear 18 and a second gear 19 through welding and fixedly sleeved with the outer side of the sleeve 9, the first gear 18 is meshed with the second gear 19, when the second motor 17 is started, the first gear 18 may rotate the second gear 19.

Referring to fig. 2, a third mounting hole is formed in the top inner wall of the first hollow groove 21, the third mounting hole is communicated with the first chute 4, a rectangular rod 22 is rotatably mounted in the third mounting hole, a worm wheel 23 is fixedly mounted at one end of the rectangular rod 22 through welding, the worm wheel 23 is meshed with the worm 20, a rectangular hole is formed in the first rotating shaft 24, the inner wall of the rectangular hole is slidably connected with the outer side of the rectangular rod 22, and when the worm 20 rotates, the worm wheel 23 can drive the rectangular rod 22 to rotate.

Referring to fig. 3, a fourth through hole is formed in the bottom inner wall of the second hollow groove 27, the fourth through hole is communicated with the rotary groove, a second rotating shaft is rotatably mounted in the fourth through hole, one end of the second rotating shaft is fixedly connected with the top of the positioning plate 14 through welding, the other end of the second rotating shaft is fixedly mounted with the outer side of the first rotating shaft 24 through welding, chain wheels 25 are meshed with the two chain wheels 25, and when the first rotating shaft 24 rotates, the two chain wheels 25 can be driven through the chain wheels 26.

Referring to fig. 4, the positioning plate 14 is rotatably installed in the rotary groove 13, two symmetrical second sliding grooves are provided at the bottom of the positioning plate 14, clamping plates 15 are slidably installed in the two second sliding grooves, a third through hole is provided at the outer side of the positioning plate 14, the third through hole is communicated with the two second sliding grooves, first threaded holes are provided on the two clamping plates 15, the same bidirectional screw rod 16 is installed in the two first threaded holes, one end of the bidirectional screw rod 16 is connected with a hand wheel, and when the hand wheel is rotated, the bidirectional screw rod 16 can drive the two clamping plates 15 to horizontally move.

In this embodiment, when in use, the refractory material can be placed between two clamping plates 15, the hand wheel is rotated, the hand wheel drives the bidirectional screw rod 16 to rotate, the bidirectional screw rod 16 drives the two clamping plates 15 to approach each other, the two clamping plates 15 can position the refractory material, then the first motor 11 is started, the first motor 11 drives the screw rod 12 to rotate, the screw rod 12 drives the mounting plate 5 to vertically move downwards, the mounting plate 5 drives the refractory material to be tested to move, when the clamping plates 15 are stopped at the inner side of the cooling shell 2, the lower end of the refractory material is placed in the heating shell 3, the fuel sprayed by the burner 6 is ignited to heat the refractory material, the internal air is conveyed through the air valve to detect the refractory property, then the sensor on the clamping plates 15 measures the temperature, the heat conduction property is measured, when the test is finished, the first motor 11 is started to reversely rotate, the refractory material is moved into the cooling shell 2, the cold air is communicated to enable the cold air nozzle 13 to spray cold air, the refractory material is cooled, the second motor 17 is started, the second motor 17 drives the worm 20 to rotate, the worm 20 drives the first gear 18 to rotate, the first gear 18 drives the second gear 19 to rotate, the second gear 19 drives the sleeve 9 to rotate, the sleeve 9 drives the cooling spray head 10 to rotate, the cooling spray head 10 can uniformly discharge the cold air, meanwhile, the worm 20 drives the worm wheel 23 to rotate, the worm wheel 23 drives the rectangular rod 22 to rotate, the rectangular rod 22 can drive the first rotating shaft 24 to rotate through the arrangement of the outer side of the rectangular rod 22 and the inner wall of the rectangular hole in a sliding manner, the first rotating shaft 24 drives the sprocket 25 to rotate, the two sprockets 25 drive the second rotating shaft through the chain 26, the second rotating shaft drives the mounting plate 5 to rotate, and the refractory material can be rotated, so that the refractory material can be rapidly cooled, and the quality detection efficiency of the refractory material is improved.

Example two

The difference between this embodiment and the first embodiment is that: the two clamping plates 15 are connected with temperature measuring sensors, the shell 1 is connected with a controller and a control switch, the control switch is connected with the second motor 17, the temperature measuring sensors, the controller and the control switch are sequentially connected, the temperature measuring sensors can monitor the temperature of refractory materials in real time, when the temperature of the refractory materials reaches a certain threshold value, the temperature measuring sensors send instructions to the controller, and the controller can start and stop the second motor 17 through the control switch, so that the refractory materials can be sufficiently and quickly cooled according to the real-time temperature of the refractory materials.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. The utility model provides a refractory material quality testing device, including casing (1), its characterized in that, first spout (4) have been seted up to one side of casing (1), install mounting panel (5) in first spout (4) sliding fit, the bottom of casing (1) is connected with cooling shell (2), the bottom of cooling shell (2) is connected with heating shell (3), combustor (6) and cooling layer (7) have been seted up in heating shell (3) in-connection, fixed mounting has fixed plate (8) in cooling shell (2), first through-hole has been seted up on fixed plate (8), sleeve pipe (9) are installed in first through-hole internal rotation, one end of sleeve pipe (9) is connected with cooling shower nozzle (10), rotary groove (13) have been seted up to the bottom of mounting panel (5), be provided with positioning mechanism in rotary groove (13), first empty slot (21) have been seted up in mounting panel (5), second empty slot (27) have been seted up on mounting panel (5), first through-hole (24) have been installed in the rotation in the second through-hole, cooling shell (2) and heating shell (3) have all been equipped with on the air valve (3).

2. The refractory material quality detection device according to claim 1, wherein the positioning mechanism comprises a positioning plate (14), the positioning plate (14) is rotatably installed in the rotary groove (13), two symmetrical second sliding grooves are formed in the bottom of the positioning plate (14), clamping plates (15) are slidably installed in the two second sliding grooves, a third through hole is formed in the outer side of the positioning plate (14), the third through hole is communicated with the two second sliding grooves, first threaded holes are formed in the two clamping plates (15), the same two-way screw rod (16) is installed in the two first threaded holes in a threaded mode, and one end of the two-way screw rod (16) is connected with a hand wheel.

3. The refractory material quality inspection device according to claim 2, wherein a fourth through hole is provided in the bottom inner wall of the second hollow groove (27), the fourth through hole is communicated with the rotary groove, a second rotating shaft is rotatably installed in the fourth through hole, one end of the second rotating shaft is fixedly connected with the top of the positioning plate (14), chain wheels (25) are fixedly installed at the other end of the second rotating shaft and the outer side of the first rotating shaft (24), and the same chain (26) is meshed on the two chain wheels (25).

4. The refractory quality inspection device according to claim 3, wherein the top of the housing (1) is fixedly provided with a first motor (11), a first mounting hole is formed in the inner wall of the top of the first chute (4), a second threaded hole is formed in the mounting plate (5), a screw (12) is mounted in the second threaded hole in a threaded manner, and one end of the screw (12) is fixedly connected with the output shaft of the first motor (11).

5. The refractory quality inspection device according to claim 4, wherein the second mounting holes are formed in one sides of the fixing plate (8) and the cooling shell (2), the second mounting holes are communicated with the first empty groove (21), the same worm (20) is rotatably mounted in the two second mounting holes, the second motor (17) is fixedly mounted on the outer side of the cooling shell (2), an output shaft of the second motor (17) is fixedly connected with one end of the worm (20), the first gear (18) and the second gear (19) are fixedly sleeved on the outer sides of the worm (20) and the sleeve (9), and the first gear (18) is meshed with the second gear (19).

6. The refractory mass detecting apparatus according to claim 4, wherein a third mounting hole is provided in the top inner wall of the first hollow groove (21), the third mounting hole is communicated with the first chute (4), a rectangular rod (22) is rotatably mounted in the third mounting hole, a worm wheel (23) is fixedly mounted at one end of the rectangular rod (22), the worm wheel (23) is engaged with the worm (20), a rectangular hole is provided in the first rotary shaft (24), and the inner wall of the rectangular hole is slidably connected with the outer side of the rectangular rod (22).