CN211122407U - Ancient tile density rapid detection equipment - Google Patents

Abstract

The utility model belongs to density check out test set field, especially, ancient tile density quick check out test set to the place frame function singleness on the current check out test set, inconvenient carries out the fixed of position to the tile of placing, causes the tile skew easily or drops when removing the place frame, causes the problem of influence to experimental data easily, now proposes following scheme, and it includes liquid container, one side fixed mounting of liquid container has the supporting seat, and slidable mounting has the link on the supporting seat, and fixed mounting has the place frame on the link, and the place groove has been seted up at the top of place frame, the tile has been placed in the place groove, has all seted up the fixed slot on the both sides inner wall of place groove. The utility model discloses rational in infrastructure, convenient operation, the place frame on this check out test set can carry out the fixed of position to the tile of placing, can not cause the tile skew or drop when removing the place frame, has guaranteed the stability of experimental data.

Description

Ancient tile density rapid detection equipment

Technical Field

The utility model relates to a density check out test set technical field especially relates to a quick check out test set of ancient tile density.

Background

In factory production, the ancient tile is arc-shaped and has chamfers, the appearance of the ancient tile is often irregular, if the ancient tile needs to ensure the quality, whether the ancient tile is qualified needs to be checked for many times, and in the checking process, the density needs to be detected, which is a very important process, for example, application number 201721023236.2 discloses a magnetic tile density rapid detection device, which relates to a density detection device and comprises a gravity detection platform and a buoyancy device, wherein a storage device is arranged on the weight measurement end face of the gravity detection platform, and the gravity detection platform is connected with a data processor; the storage device comprises a supporting seat arranged on the weight measuring end face of the gravity detection table, a placement frame is arranged on the supporting seat in a vertically sliding mode and is located above the buoyancy device, and an adjusting assembly is arranged on the supporting seat. And measuring gravity data m1 when the magnetic tile is placed in air and gravity data m2 when the magnetic tile is placed in liquid in advance, placing the magnetic tile to be detected on the placement frame, wherein the overall weight of the magnetic tile to be detected in air is m3, the weight of the magnetic tile to be detected in liquid is m4, and rho & ltmaterial & gt (m3-m1) rho liquid/(m 2+ m3-m1-m4) according to the formula. The whole equipment automatically detects the density of the irregular object according to the Archimedes principle, has high detection speed and low use threshold, and improves the detection efficiency of laboratories and factories;

however, the placement frame on the detection equipment has a single function, is inconvenient to fix the placed tiles, easily causes tile deviation or falling off when the placement frame is moved, and easily causes influence on experimental data.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the function of the placing frame on the detection equipment is single in the prior art, the placing frame is inconvenient to fix the place of the tile, the tile is easy to shift or fall off when the placing frame is moved, the defect of influence is easily caused to the experimental data, and the quick detection equipment for the ancient tile density is provided.

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

the utility model provides a ancient tile density short-term test equipment, includes liquid container, one side fixed mounting of liquid container has the supporting seat, and slidable mounting has the link on the supporting seat, and fixed mounting has the mount frame on the link, and the mounting groove has been seted up at the top of mount frame, the tile has been placed in the mounting groove, has all seted up the fixed slot on the both sides inner wall of mounting groove, and equal slidable mounting has the grip block in two fixed slots, and one side that two grip blocks are close to each other all contacts with the tile, set up two recesses on the bottom inner wall of mounting groove, equal slidable mounting has the control cabinet in two recesses, and the top of two control cabinets all contacts with the tile.

Preferably, first thread grooves have all been seted up to the bottom of two control seats, the screw rod has all been installed to equal screw thread in two first thread grooves, the bottom of two screw rods is all rotated and is installed on the bottom inner wall of two corresponding recesses, all fixed cover is equipped with first bevel gear on two screw rods, the second thread groove has all been seted up to the one end that two grip blocks kept away from each other, the lead screw is installed to equal screw thread in two second thread grooves, the control seat slides in the recess and drives the screw rod and rotate, the screw rod drives first bevel gear and rotates.

Preferably, the one end that two lead screws kept away from each other all rotates to be installed on the inner wall of two fixed slots that correspond, and all fixed cover is equipped with first belt pulley on two lead screws, has seted up fixed chamber on the mount frame, has seted up same through-hole on one side inner wall that fixed chamber and recess are close to each other, and the dwang is installed to the through-hole internal rotation, and the dwang drives the second belt pulley and rotates at fixed intracavity, and the second belt pulley drives belt drive.

Preferably, the one end of dwang extends to in the recess and fixed mounting has second bevel gear, second bevel gear and the meshing of first bevel gear, and the other end of dwang extends to fixed intracavity and fixed mounting has the second belt pulley, and the meshing has same belt on second belt pulley and the first belt pulley, and first bevel gear drives second bevel gear and rotates, and second bevel gear drives the dwang and rotates.

Preferably, a rotating groove is formed in the inner wall of the groove, one end of the screw rod is rotatably installed in the rotating groove, a connecting groove is formed in the inner wall of one side of the fixing groove, one end of the screw rod is rotatably installed in the connecting groove, and the position of the screw rod during rotation can be stabilized through rotation of the screw rod in the connecting groove.

Compared with the prior art, the beneficial effects of the utility model reside in that:

(1) according to the scheme, the tiles are placed in the placing grooves, the tiles press the two control seats, the screw rod drives the first bevel gear to rotate, the first bevel gear drives the second bevel gear to rotate, the rotating rod drives the second belt pulley to rotate in the fixed cavity, and the second belt pulley drives the belt to transmit;

(2) according to the scheme, a belt drives a first belt pulley to rotate, the first belt pulley drives a screw rod to rotate, clamping blocks slide out of a fixing groove and are in contact with tiles, the two clamping blocks clamp the tiles and are temporarily fixed in a placing groove, and a connecting frame drives the placing frame to be placed in a liquid container to calculate the density of the tiles;

the utility model discloses rational in infrastructure, convenient operation, the place frame on this check out test set can carry out the fixed of position to the tile of placing, can not cause the tile skew or drop when removing the place frame, has guaranteed the stability of experimental data.

Drawings

Fig. 1 is a schematic view of a front view structure of a device for rapidly detecting the density of ancient tiles according to the present invention;

fig. 2 is a schematic structural view of a part a of the device for rapidly detecting the density of the ancient tiles of the present invention;

fig. 3 is a schematic structural view of a part B of the device for rapidly detecting the density of the ancient tiles of the present invention;

fig. 4 is the utility model provides a ancient tile density short-term test equipment's part C schematic structure.

In the figure: 1. a liquid container; 2. a supporting seat; 3. a connecting frame; 4. a placement frame; 5. a placing groove; 6. a tile; 7. fixing grooves; 8. a clamping block; 9. a screw rod; 10. a first pulley; 11. a groove; 12. a control seat; 13. a first thread groove; 14. a screw; 15. a first bevel gear; 16. rotating the rod; 17. a second bevel gear; 18. a second pulley; 19. a belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Example 1

Referring to fig. 1-4, a ancient tile density quick detection equipment, including liquid container 1, one side fixed mounting of liquid container 1 has supporting seat 2, slidable mounting has link 3 on supporting seat 2, fixed mounting has place frame 4 on the link 3, place 5 of groove has been seted up at place 4's top, place tile 6 in the groove 5, fixed slot 7 has all been seted up on place 5's the both sides inner wall, equal slidable mounting has grip block 8 in two fixed slots 7, one side that two grip block 8 are close to each other all contacts with tile 6, two recesses 11 have been seted up on place 5's the bottom inner wall, equal slidable mounting has control cabinet 12 in two recesses 11, the top of two control cabinets 12 all contacts with tile 6.

In this embodiment, first thread groove 13 has all been seted up to the bottom of two control seats 12, screw rod 14 has been installed to equal screw thread in two first thread grooves 13, the bottom of two screw rods 14 is all rotated and is installed on the bottom inner wall of two recesses 11 that correspond, equal fixed cover is equipped with first bevel gear 15 on two screw rods 14, the second thread groove has all been seted up to the one end that two grip blocks 8 kept away from each other, lead screw 9 is installed to equal screw thread in two second thread grooves, control seat 12 slides and drives screw rod 14 and rotate in recess 11, screw rod 14 drives first bevel gear 15 and rotates.

In this embodiment, the one end that two lead screws 9 kept away from each other all rotates and installs on the inner wall of two fixed slots 7 that correspond, and equal fixed cover is equipped with first belt pulley 10 on two lead screws 9, has seted up fixed chamber on the mount 4, has seted up same through-hole on one side inner wall that fixed chamber and recess 11 are close to each other, and dwang 16 is installed to the through-hole internal rotation, and dwang 16 drives second belt pulley 18 and rotates at fixed intracavity, and second belt pulley 18 drives the transmission of belt 19.

In this embodiment, the one end of dwang 16 extends to in the recess 11 and fixed mounting has second bevel gear 17, second bevel gear 17 and the meshing of first bevel gear 15, and the other end of dwang 16 extends to fixed intracavity and fixed mounting has second belt pulley 18, and the meshing has same belt 19 on second belt pulley 18 and the first belt pulley 10, and first bevel gear 15 drives second bevel gear 17 and rotates, and second bevel gear 17 drives dwang 16 and rotates.

In this embodiment, a rotation groove has been seted up on the inner wall of recess 11, and the one end of screw rod 14 is rotated and is installed in rotating the inslot, has seted up the spread groove on one side inner wall of fixed slot 7, and the one end of lead screw 9 is rotated and is installed in the spread groove, and the position when lead screw 9 rotated can be stabilized in the spread groove internal rotation to lead screw 9.

Example 2

Referring to fig. 1-4, a ancient tile density short-term test equipment, including liquid container 1, there is supporting seat 2 one side of liquid container 1 through bolt fixed mounting, slidable mounting has link 3 on supporting seat 2, there is mount 4 through bolt fixed mounting on link 3, mount 5 has been seted up at mount 4's top, tile 6 has been placed in mount 5, fixed slot 7 has all been seted up on mount 5's the both sides inner wall, equal slidable mounting has grip block 8 in two fixed slots 7, one side that two grip blocks 8 are close to each other all contacts with tile 6, two recesses 11 have been seted up on mount 5's the bottom inner wall, equal slidable mounting has control pedestal 12 in two recesses 11, the top of two control pedestals 12 all contacts with tile 6.

In this embodiment, first thread groove 13 has all been seted up to the bottom of two control seats 12, screw rod 14 has been installed to equal screw thread in two first thread grooves 13, the bottom of two screw rods 14 is all rotated and is installed on the bottom inner wall of two recesses 11 that correspond, equal fixed cover is equipped with first bevel gear 15 on two screw rods 14, the second thread groove has all been seted up to the one end that two grip blocks 8 kept away from each other, lead screw 9 is installed to equal screw thread in two second thread grooves, control seat 12 slides and drives screw rod 14 and rotate in recess 11, screw rod 14 drives first bevel gear 15 and rotates.

In this embodiment, the one end that two lead screws 9 kept away from each other all rotates and installs on the inner wall of two fixed slots 7 that correspond, and equal fixed cover is equipped with first belt pulley 10 on two lead screws 9, has seted up fixed chamber on the mount 4, has seted up same through-hole on one side inner wall that fixed chamber and recess 11 are close to each other, and dwang 16 is installed to the through-hole internal rotation, and dwang 16 drives second belt pulley 18 and rotates at fixed intracavity, and second belt pulley 18 drives the transmission of belt 19.

In this embodiment, the one end of dwang 16 extends to in the recess 11 and has second bevel gear 17 through bolt fixed mounting, second bevel gear 17 and the meshing of first bevel gear 15, the other end of dwang 16 extends to fixed intracavity and has second belt pulley 18 through bolt fixed mounting, the meshing has same belt 19 on second belt pulley 18 and the first belt pulley 10, first bevel gear 15 drives second bevel gear 17 and rotates, second bevel gear 17 drives dwang 16 and rotates.

In this embodiment, a rotation groove has been seted up on the inner wall of recess 11, and the one end of screw rod 14 is rotated and is installed in rotating the inslot, has seted up the spread groove on one side inner wall of fixed slot 7, and the one end of lead screw 9 is rotated and is installed in the spread groove, and the position when lead screw 9 rotated can be stabilized in the spread groove internal rotation to lead screw 9.

In this embodiment, the liquid container 1, the supporting seat 2, the connecting frame 3, the placing frame 4, the placing groove 5, the tile 6, the fixing groove 7, the clamping block 8, the screw rod 9, the first belt pulley 10, the groove 11, the control seat 12, the first thread groove 13, the screw rod 14, the first bevel gear 15, the rotating rod 16, the second bevel gear 17, the second belt pulley 18 and the belt 19 are all universal standard components or components known by those skilled in the art, and the structure and principle of the components are all known by technical manuals or obtained by a conventional experimental method, in the first step, the weight data of the placing frame 4 in the air is measured by a gravity detection table, the data processor is recorded as m1, in the second step, the connecting frame 3 is pressed down to drive the placing frame 4 to directly enter the liquid container 1, the weight data of the placing frame 4 entering the liquid is measured by the gravity detection table, the data processor is recorded as m2, thirdly, placing the tiles 6 in the placing groove 5, measuring the integral weight data of the placing frame 4 and the tiles 6 in the air through a gravity detection table, recording the data as m3 by a data processor, pressing the two control seats 12 by the tiles 6, sliding the control seats 12 in the grooves 11 and driving the screw 14 to rotate, driving the first bevel gear 15 to rotate by the screw 14, driving the second bevel gear 17 to rotate by the first bevel gear 15, driving the second bevel gear 17 to rotate by the second bevel gear 17, driving the second belt pulley 18 to rotate in the fixed cavity by the rotating rod 16, driving the belt 19 to transmit by the second belt pulley 18, driving the first belt pulley 10 to rotate by the belt 19, driving the screw 9 to rotate by the first belt pulley 10, driving the clamping fixed groove 8 to move by the screw 9, sliding the clamping block 8 out of 7 and contacting with the tiles 6, clamping the tiles 6 by the two clamping blocks 8 and temporarily fixing the tiles 6 in the placing groove 5, the connecting frame 3 slides, the connecting frame 3 drives the placing frame 4 to be placed in the liquid container 1, the whole weight data when the placing frame 4 and the tiles 6 enter the liquid container 1 is measured through the gravity detection platform, the data processor records data as m4, after the data processor collects the data, the final data is rho (m3-m1)/(m2+ m3-m1-m4) because the injected liquid is water and the rho water is 1g/cm3 according to the formula rho (m3-m1)/(m2+ m3-m1-m4), the data processor displays the final density rho of the tiles 6, the data processor and the gravity detection platform are both the prior art, the utility model has reasonable structure and convenient operation, the placing frame 4 on the detection device can fix the positions of the placed tiles 6, the tiles 6 can not be deviated or fall off when the placing frame 4 is moved, and the stability of experimental data is ensured.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (3)

1. The device for rapidly detecting the ancient tile density comprises a liquid container (1) and is characterized in that a supporting seat (2) is fixedly arranged on one side of the liquid container (1), a connecting frame (3) is slidably arranged on the supporting seat (2), a placing frame (4) is fixedly arranged on the connecting frame (3), a placing groove (5) is formed in the top of the placing frame (4), tiles (6) are placed in the placing groove (5), fixing grooves (7) are formed in the inner walls of the two sides of the placing groove (5), clamping blocks (8) are slidably arranged in the two fixing grooves (7), one sides of the two clamping blocks (8) close to each other are in contact with the tiles (6), two grooves (11) are formed in the inner wall of the bottom of the placing groove (5), control seats (12) are slidably arranged in the two grooves (11), and the tops of the two control seats (12) are in contact with the tiles (6), first thread groove (13) have all been seted up to the bottom of two control seats (12), equal threaded mounting has screw rod (14) in two first thread grooves (13), the bottom of two screw rods (14) is all rotated and is installed on the bottom inner wall of two recesses (11) that correspond, equal fixed cover is equipped with first bevel gear (15) on two screw rods (14), the second thread groove has all been seted up to the one end of keeping away from each other of two grip blocks (8), equal threaded mounting has lead screw (9) in two second thread grooves, the one end of keeping away from each other of two lead screw (9) is all rotated and is installed on the inner wall of two fixed slots (7) that correspond, equal fixed cover is equipped with first belt pulley (10) on two lead screw (9), set up fixed chamber on frame (4), same through-hole has been seted up on the one side inner wall that fixed chamber and recess (11) are close to each other, dwang (16).

2. The device for rapidly detecting the ancient tile density according to claim 1, wherein one end of the rotating rod (16) extends into the groove (11) and is fixedly provided with a second bevel gear (17), the second bevel gear (17) is meshed with the first bevel gear (15), the other end of the rotating rod (16) extends into the fixed cavity and is fixedly provided with a second belt pulley (18), and the second belt pulley (18) and the first belt pulley (10) are meshed with a same belt (19).

3. The device for rapidly detecting the density of the ancient tiles as claimed in claim 1, wherein the inner wall of the groove (11) is provided with a rotating groove, one end of the screw rod (14) is rotatably installed in the rotating groove, one side of the inner wall of the fixed groove (7) is provided with a connecting groove, and one end of the screw rod (9) is rotatably installed in the connecting groove.

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