CN112798054B - Window check out test set - Google Patents

Abstract

The application relates to a window detection device, which comprises a first detection device, a second detection device and a transfer device, wherein the second detection device is arranged on one side of the first detection device, and the transfer device transfers a window from the first detection device to the second detection device; the first detection device comprises a first main body, a water outlet pipe, an air outlet pipe, a cover body, a first sensor, a second sensor, a third sensor, a deflection detection mechanism and a division mechanism, wherein a placing area is formed on the first main body, and the water outlet pipe and the air outlet pipe are both arranged in the first main body; the dividing mechanism is arranged in the first main body and divides the placing area into different testing areas; the cover body is connected with the first main body, the deflection detection mechanism is arranged on the cover body, the first sensor and the second sensor are both arranged on the cover body, and the third sensor is arranged on the deflection detection mechanism. This application has the effect that improves window check out test set's detection efficiency.

Description

Window detection equipment

Technical Field

The application relates to the technical field of window detection, especially, relate to a window check out test set.

Background

The window performance detection mainly detects the water tightness, air tightness and wind pressure resistance of the building outer window.

At present, chinese patent with publication number CN211013777U discloses a window performance detection device, including examining a body, examine a body and include frame and clamping part and the experimental part of setting in the frame, the position that is close to the clamping part in the frame is equipped with the material loading subassembly, the material loading subassembly includes the last flitch of sliding connection mount pad in the frame with the slope setting, it sets up downwards to the direction slope that is close to the clamping part to go up the flitch one end that is close to the clamping part, and articulate on the mount pad, upward be provided with the mounting that is used for fixed door and window on the flitch, and be provided with the drive assembly that the flitch overturned to being close to the clamping part in the drive on the flitch.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: when detecting the window, only one window can be detected at a time, and the efficiency is low.

Disclosure of Invention

In order to improve window check out test set's detection efficiency, this application provides a window check out test set.

The application provides a window check out test set adopts following technical scheme:

a window detecting apparatus includes a first detecting device, a second detecting device disposed at a side of the first detecting device, and a transferring device that transfers a window from the first detecting device to the second detecting device; the first detection device comprises a first main body, a water outlet pipe, an air outlet pipe, a cover body, a first sensor, a second sensor, a third sensor, a deflection detection mechanism and a division mechanism, wherein a placing area is formed on the first main body, and the water outlet pipe and the air outlet pipe are both arranged in the first main body; the dividing mechanism is arranged in the first main body and divides the placing area into different testing areas; the cover body is connected with the first main body, the deflection detection mechanism is arranged on the cover body, the first sensor and the second sensor are both arranged on the cover body, and the third sensor is arranged on the deflection detection mechanism.

By adopting the technical scheme, the window is divided into a plurality of detection areas by the dividing mechanism, then the window is placed in the corresponding test area, and each test area is an independent space, so that different tests in different test areas cannot be influenced; the first sensor detects the air permeability of the window glass, the second sensor detects whether the window leaks water when raining, and the third sensor detects the deflection of the window under the condition of strong wind; the detection equipment who sets up can a plurality of windows of concurrent test, and can not influence each other to improve detection efficiency.

Optionally, a first sliding groove is formed in the upper end of the first main body, the dividing mechanism includes a first sliding block, a dividing plate, a first screw rod and a first motor, the first sliding block is connected in the first sliding groove in a sliding manner, and the first screw rod is arranged in the first sliding groove and connected with the first sliding block; the first motor is arranged on the first main body and is connected with the first screw rod; the placing area is divided into different testing areas by the partition plate, the partition plate comprises a main plate, an auxiliary plate, an adjusting rod, a second motor, a first gear and a first rack, the main plate is connected with the first sliding block, a first groove is formed in the main plate, the auxiliary plate is connected in the first groove in a sliding mode and abuts against the side wall of the first main body, the adjusting rod is arranged on the auxiliary plate, and the first rack is arranged on the adjusting rod; the second motor is arranged on the main board, and the first gear is connected to an output shaft of the second motor in a key mode and meshed with the first rack.

By adopting the technical scheme, when two windows are detected, the first motor is started, the output shaft of the first motor drives the first screw rod to rotate, the first screw rod drives the first sliding block to slide in the first sliding groove, the first sliding block drives the main board to move, the first motor is closed after the first sliding block moves to a proper position, the second motor is started, the output shaft of the second motor drives the first gear to rotate, the first rack meshed with the first gear drives the adjusting rod to move, and the adjusting rod drives the auxiliary board to slide in the first groove of the main board and abut against the first main body; the cutting mechanism is simple in structure and can avoid the air outlet pipe and the water outlet pipe, and the partition plate is prevented from being damaged by the air outlet pipe and the water outlet pipe in the movement process.

Optionally, the cross-sectional area of the test area is larger than that of the window, a connecting plate is arranged on the first main body, and the connecting plate and the window jointly cover the placement area; the cover body is provided with a second chute, the deflection detection mechanism comprises a second sliding block, a first connecting block, a third motor, a second gear, a second rack and a detection assembly, the second sliding block is connected in the second chute in a sliding manner, the third motor is arranged on the second sliding block, and the second gear is connected to an output shaft of the third motor in a key manner; the second rack is arranged on the side wall of the second sliding chute and is meshed with the second gear; the first connecting block is arranged on the second sliding block; the detection assembly comprises a magnet block, a second connecting block, a third connecting block, a fourth connecting block, a first bolt, a test rod, a spring and a ball, the magnet block is connected with the first connecting block, the second connecting block is arranged on the magnet block, a second groove is formed in the second connecting block, and the third connecting block is arranged in the second groove; a first threaded hole is formed in the second connecting block, and the first bolt is in threaded connection with the first threaded hole and abuts against the third connecting block; a sliding hole is formed in the third connecting block, the testing rod is connected in the sliding hole in a sliding mode, and the third sensor is arranged on the testing rod; the fourth connecting block is arranged on the testing rod, and the ball is arranged on the fourth connecting block and abuts against the window; the spring is sleeved on the test rod, one end of the spring is connected with the third connecting block, and the other end of the spring is connected with the fourth connecting block.

By adopting the technical scheme, when the deflection of the window needs to be tested, the window is placed in the testing area, the third motor is started according to the height of the window, the output shaft of the third motor drives the second gear to rotate, and the second gear is meshed with the second rack, so that when the second gear rotates, the second gear can move relative to the second rack, and the second gear can drive the second sliding block to slide in the second sliding groove; then adhering the magnet block to the first connection block at different positions; then, the cover body is connected to the first main body, so that the ball can abut against the window, then strong wind is introduced into a test area for placing the window, when the window deforms, the ball can drive the fourth connecting block to move towards the direction close to the third connecting block, and the test rod can slide in the sliding hole; the deflection detection mechanism is simple and convenient to operate and can detect windows of different sizes.

Optionally, the connecting plate includes a first sealing plate and a second sealing plate, the first sealing plate is disposed at the upper end of the first main body, the second sealing plate is connected to the first sealing plate, and the second sealing plate, the first sealing plate and the window seal the placement area; a connecting assembly is arranged between the first sealing plate and the second sealing plate, the connecting assembly comprises a fifth connecting block and a second bolt, one end of the fifth connecting block abuts against the second sealing plate, the other end of the fifth connecting block is provided with a second threaded hole, the second bolt is in threaded connection with the second threaded hole, and the second bolt penetrates through the second threaded hole and abuts against the first sealing plate; the first main body is provided with a fixing assembly, the fixing assembly comprises an adjusting block, a fixing plate, a third bolt and a fourth bolt, a first through hole is formed in the adjusting block, a third threaded hole is formed in the first main body, and the third bolt penetrates through the first through hole and is in threaded connection with the third threaded hole; the adjusting block is provided with a fourth threaded hole, a fourth bolt is in threaded connection with the fourth threaded hole, the fixing plate is in threaded connection with the fourth bolt, and the fixing plate abuts against the first sealing plate, the second sealing plate and the window.

By adopting the technical scheme, the window is arranged on the first main body, when the windows with different heights are detected simultaneously, the first sealing plate is determined according to the window with the highest relative height, and then the second sealing plate is used for connecting the first sealing plate and the window; and then one end of the fifth connecting block is abutted against the second sealing plate, and then the second bolt is selected, and because the second bolt is in threaded connection with the second threaded hole, when the second bolt rotates, the second bolt can displace relative to the second threaded hole, so that the second bolt is abutted against the first sealing plate. Finally, a third bolt penetrates through a first through hole in the adjusting block to be in threaded connection with a third threaded hole, and the adjusting block is fixed on the first main body; then the fourth bolt is rotated, because the fourth bolt is in threaded connection with the fourth threaded hole, when the fourth bolt rotates, the fixing plate moves, so that different fixing plates abut against the first sealing plate, the second sealing plate and the window. The connecting plate of setting not only can seal the window of equidimension not, can consolidate the window that is located on first main part moreover.

Optionally, a fixing mechanism connected with the cover body is arranged on the first main body, the fixing mechanism includes a fixing block, a fixing rod and a first adjusting assembly, the fixing block is arranged on the first main body, and a third groove is formed in the fixing block; one end of the fixed rod is connected in the third groove in a sliding manner, and the other end of the fixed rod is connected with the cover body; the first adjusting assembly comprises a fourth motor, a third gear and a third rack, the fourth motor is arranged on the fixed block, and the third gear is in key connection with an output shaft of the fourth motor; the third rack is arranged on the fixed rod and meshed with the third gear.

By adopting the technical scheme, the fourth motor is started, the output shaft of the fourth motor drives the third gear to rotate, the third rack meshed with the third gear drives the fixed rod to move, and the fixed rod drives the cover body to move towards the direction close to the first main body; and when the first detection device finishes detecting, the fixing mechanism can fix the position of the cover body, and the cover body movement is prevented from influencing the loading and transportation of the transfer device.

Optionally, the second detection device includes a second main body, a partition wall, a flow guide plate, a heat insulation plate, and a fourth sensor, the partition wall is disposed in the second main body, and the partition wall divides the second main body into a cold bin and a hot bin, a placement hole for placing a window is formed in the partition wall, and the placement hole communicates the cold bin and the hot bin; the cross section area of the placing hole is larger than that of the window, and a heat insulation plate abutting against the window is arranged on the side wall of the placing hole; the guide plate is arranged on one side of the hot bin close to the partition wall, and the fourth sensor is positioned between the partition wall and the guide plate.

By adopting the technical scheme, when the heat insulation performance of the window is required, the window is placed in the placing hole of the partition wall, and then the heat insulation plate is connected to the side wall of the placing hole and the side wall of the placing hole, so that the heat insulation plate and the window are sealed together to form the placing hole; then detecting the heat insulation performance of the window through a fourth sensor; the second detection device is simple in structure and convenient to operate.

Optionally, a connecting mechanism is arranged in the hot bin, the connecting mechanism includes a first rotating shaft, a second rotating shaft, a winding disc, a connecting rope, a limiting rod, a second adjusting assembly and a third adjusting assembly, the first rotating shaft is arranged on the second main body, the second rotating shaft is located between the guide plate and the partition wall, the winding disc is arranged on the second rotating shaft, the connecting rope is connected with the winding disc, and the fourth sensor is connected with the connecting rope; the second rotating shaft is arranged on the rolling disc, and the limiting rod is arranged on the second rotating shaft and abuts against the connecting rope on the rolling disc; the second adjusting assembly comprises a fourth gear, a fifth gear and a fifth motor, the fifth motor is arranged on the second main body, an output shaft of the fifth motor is in keyed connection with the fourth gear, and the first rotating shaft is in keyed connection with the fifth gear meshed with the fourth gear; the third adjusting assembly comprises a sixth gear, a seventh gear and a sixth motor, the sixth motor is arranged on the winding disc, and the sixth gear is in keyed connection with the sixth motor; and the seventh gear is connected to the second rotating shaft in a keyed mode and is meshed with the sixth gear.

By adopting the technical scheme, after the window is installed on the partition wall in the second main body, the fifth motor is started firstly, the output shaft of the fifth motor drives the fourth gear to rotate, the fifth gear meshed with the fourth gear drives the first rotating shaft to rotate, and the first rotating shaft drives the rolling disc to rotate; then starting a sixth motor on one of the winding disks, wherein an output shaft of the sixth motor drives a sixth gear to rotate, a seventh gear meshed with the sixth gear rotates, the seventh gear drives a second rotating shaft to rotate, the second rotating shaft drives a limiting rod to move, so that the limiting rod does not conflict with a connecting rope any more, when the first rotating shaft rotates, the connecting rope on the winding disk winds out of the winding disk, the connecting ropes on other winding disks cannot wind out, and then the sixth motors on other collecting disks are started in sequence, so that the relative heights of the fourth sensors on the connecting ropes are different and correspond to different positions of a window; the connecting mechanism can improve the detection accuracy.

Optionally, the transfer device includes a cart, a hydraulic cylinder, a lifting table, a clamping block, and a fourth adjusting assembly, the hydraulic cylinder is disposed on the cart, the lifting table is disposed on a piston rod of the hydraulic cylinder, a third sliding groove is disposed on the lifting table, and both ends of the third sliding groove are connected to the clamping block in a sliding manner; the fourth adjusting assembly comprises a bidirectional screw and a seventh motor, the bidirectional screw is rotatably connected in the third sliding groove, and the two clamping blocks are respectively connected with two ends of the bidirectional screw; the seventh motor is arranged on the lifting platform and connected with the bidirectional screw rod.

Through adopting above-mentioned technical scheme, when transporting the window, place the window between two grip blocks earlier, then start seventh motor, the output shaft of seventh motor drives two-way screw rod and rotates, two-way screw rod drives two grip blocks and is the motion in opposite directions, make two grip block centre gripping windows, then promote the shallow, in transporting the window to the second detection device from first detection device, when the window size changes, start the hydraulic cylinder, the position that makes the elevating platform takes place to be convenient for, the operating personnel of being convenient for moves the window.

To sum up, this application includes following at least one kind of window check out test set beneficial technical effect:

1. the arranged detection equipment can simultaneously test a plurality of windows without mutual influence, so that the detection efficiency is improved;

2. the arranged connecting plate not only can seal windows with different sizes, but also can reinforce the windows on the first main body;

3. the connecting mechanism can improve the detection accuracy.

Drawings

FIG. 1 is a schematic structural diagram of a window inspection apparatus according to an embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a connecting plate in an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a dividing mechanism in an embodiment of the present application;

FIG. 4 is a schematic structural diagram of a deflection detection mechanism in an embodiment of the present application;

FIG. 5 is a schematic structural diagram of a detection assembly according to an embodiment of the present disclosure;

FIG. 6 is a schematic structural view of a fixing mechanism in an embodiment of the present application;

FIG. 7 is a schematic structural view of a coupling mechanism according to an embodiment of the present application;

FIG. 8 is a schematic structural diagram of a third adjustment assembly in an embodiment of the present application;

fig. 9 is a schematic structural diagram of a transfer device in an embodiment of the present application.

Reference numerals: 1. a first detection device; 11. a first body; 12. a cover body; 121. a second chute; 2. a dividing mechanism; 21. a first slider; 22. a first screw; 23. a first motor; 241. a main board; 2411. a first groove; 242. a sub-board; 243. adjusting a rod; 244. a second motor; 245. a first gear; 246. a first rack; 3. a deflection detection mechanism; 31. a second slider; 32. a first connection block; 33. a second gear; 34. a second rack; 35. a detection component; 351. a magnet block; 352. a second connecting block; 3521. a second groove; 353. a third connecting block; 354. a fourth connecting block; 355. a first bolt; 356. a test rod; 357. a spring; 358. a ball bearing; 4. a connecting plate; 41. a first sealing plate; 42. a second sealing plate; 43. a connecting assembly; 431. a fifth connecting block; 432. a second bolt; 44. a fixing assembly; 441. an adjusting block; 442. a fixing plate; 443. a third bolt; 444. a fourth bolt; 45. a fifth bolt; 5. a fixing mechanism; 51. a fixed block; 511. a third groove; 52. fixing the rod; 53. a first adjustment assembly; 531. a fourth motor; 532. a third gear; 533. a third rack; 6. a second detection device; 61. a second body; 62. a dividing wall; 63. a baffle; 64. a thermal insulation board; 7. a connecting mechanism; 71. a first rotating shaft; 72. a winding disc; 73. a support block; 74. connecting ropes; 75. a restraining bar; 76. a second adjustment assembly; 761. a fourth gear; 762. a fifth gear; 763. a fifth motor; 77. a third adjustment assembly; 771. a sixth gear; 772. a seventh gear; 773. a sixth motor; 78. a sixth connecting block; 79. a seventh connecting block; 8. a transfer device; 81. pushing a cart; 82. a lifting platform; 821. a third chute; 83. a clamping block; 84. a fourth adjustment assembly; 841. a bidirectional screw; 842. and a seventh motor.

Detailed Description

The present application is described in further detail below with reference to figures 1-9.

The embodiment of the application discloses window check out test set.

Referring to fig. 1, the window detecting apparatus includes a first detecting device 1, a second detecting device 6, and a transferring device 8; the window is first inspected in the first inspection device 1 and the transfer device 8 transfers the first inspection device 1 to the second inspection device 6.

Referring to fig. 1 and 2, the first detecting device 1 includes a first main body 11, a placing area is formed in the first main body 11, a water outlet pipe and an air outlet pipe are arranged in the first main body 11, and the water outlet pipe and the air outlet pipe are both located in the placing area.

Referring to fig. 2 and 3, a first sliding groove is formed at the upper end of the first main body 11, a dividing mechanism 2 is arranged in the first main body 11, and the dividing mechanism 2 includes a first sliding block 21 connected in the first sliding groove in a sliding manner; a first screw 22 is rotatably connected in the first sliding groove, and the first screw 22 passes through the first sliding block 21 and is in threaded connection with the first sliding block 21; a first motor 23 connected to the first screw 22 is fixedly connected to the first body 11.

The first sliding block 21 is provided with a partition plate which divides the placing area into two testing areas, and the cross sectional area of each testing area is larger than that of a window; the partition plate comprises a main plate 241 fixedly connected to the first slider 21, a first groove 2411 is formed in the main plate 241, an auxiliary plate 242 is connected to the first groove 2411 in a sliding mode, a sealing gasket tightly abutting against the side wall of the first main body 11 is fixedly connected to one end, away from the first groove 2411, of the auxiliary plate 242, an adjusting rod 243 is fixedly connected to one end, located in the first groove 2411, of the auxiliary plate 242, and a first rack 246 is integrally arranged on the adjusting rod 243; a second motor 244 is fixedly connected to the main plate 241, and a first gear 245 engaged with the first rack 246 is keyed on an output shaft of the second motor 244.

When a larger window needs to be detected, or two windows with different sizes need to be detected, the first motor 23 is started first, the output shaft of the first motor 23 drives the first screw 22 to rotate, the first screw 22 drives the first sliding block 21 to slide in the first sliding groove, the first sliding block 21 drives the main board 241 to move, after the main board moves to a proper position, the first motor 23 is closed, the second motor 244 is started, the output shaft of the second motor 244 drives the first gear 245 to rotate, the first rack 246 meshed with the first gear 245 drives the adjusting rod 243 to move, the adjusting rod 243 drives the auxiliary board 242 to slide in the first groove 2411 of the main board 241, and the sealing gasket on the auxiliary board 242 abuts against the first main body 11.

Referring to fig. 2, the cross-sectional area of the test zone is larger than that of the window, a connection plate 4 is provided on the first body 11, the connection plate 4 includes a first sealing plate 41, and the first sealing plate 41 is connected to the first body 11 by a fifth bolt 45; the first sealing plate 41 is provided with a plurality of first sealing plates 41, the number of the first sealing plates 41 can be selected according to the height of the window, and glass cement is arranged between every two adjacent first sealing plates 41. A second sealing plate 42 is connected to one end of the first sealing plate 41 close to the window, and glass cement is filled between the first sealing plate 41 and the second sealing plate 42, between the second sealing plate 42 and the window, between the window and the first main body 11, and between the window and the main board 241; the first sealing plate 41, the second sealing plate 42 and the window sealing placement area.

All be provided with coupling assembling 43 between first sealing plate 41 and the second sealing plate 42, coupling assembling 43 includes fifth connecting block 431, and fifth connecting block 431 is transversal to personally submit the C type, and the one end of fifth connecting block 431 supports tightly second sealing plate 42, and the second screw hole has been seted up to the other one end of fifth connecting block 431, and threaded connection has second bolt 432 in the second screw hole, and second bolt 432 supports tightly first sealing plate 41. The same connecting assembly 43 is also arranged between two adjacent first sealing plates 41, one end of a fifth connecting block 431 in the connecting assembly 43 abuts against one of the first sealing plates 41, and the second bolt 432 abuts against the adjacent first sealing plate 41.

The fixing assemblies 44 are arranged on the first main body 11 and the main board 241, each fixing assembly 44 comprises an adjusting block 441, a first through hole is formed in each adjusting block 441, a third threaded hole is formed in the first main body 11, and a third bolt 443 penetrating through the first through hole and in threaded connection with the third threaded hole is arranged on each adjusting block 441; a fourth threaded hole is formed in one end, away from the first through hole, of the adjusting block 441, a fourth bolt 444 is connected to the inner thread of the fourth threaded hole, a fixing plate 442 is connected to the fourth bolt 444, and the fixing plate 442 can abut against the first sealing plate 41, the second sealing plate 42 and the window.

The window is mounted on the first body 11, and when the windows of different heights are inspected, the number of the first sealing plate 41 is determined according to the window having the highest relative height, and then the first sealing plate 41 is coupled to the first body 11 by the fifth bolt 45, and then the first sealing plate 41 and the window are coupled by the second sealing plate 42.

Then, one end of the fifth connecting block 431 abuts against the second sealing plate 42, and then the second bolt 432 is rotated, because the second bolt 432 is in threaded connection with the second threaded hole, when the second bolt 432 rotates, the second bolt 432 will displace relative to the second threaded hole, so that the second bolt 432 abuts against the first sealing plate 41 close to the second sealing plate 42; then connecting the adjacent two first sealing plates 41 with a connecting assembly 43; finally, glass cement is applied between two adjacent first sealing plates 41, first sealing plates 41 and second sealing plates 42, second sealing plates 42 and windows, windows and the first main body 11, and windows and the main plate 241.

Finally, a third bolt 443 is threaded through the first through hole in the adjusting block 441 and is connected with the third threaded hole, and the adjusting block 441 is fixed on the first main body 11 and the main board 241; then, the fourth bolt 444 is rotated, and since the fourth bolt 444 is threadedly coupled to the fourth threaded hole, when the fourth bolt 444 is rotated, the fixing plate 442 moves such that different fixing plates 442 abut against the first sealing plate 41, the second sealing plate 42 and the window.

Referring to fig. 1 and 4, a cover 12 is provided on a first body 11, and a first sensor for detecting air permeability of a window glass and a second sensor for detecting whether water leaks when the window is rainy are provided on the cover 12.

A second chute 121 is formed in the cover body 12, a deflection detection mechanism 3 is arranged on the cover body 12, the deflection detection mechanism 3 comprises a second slide block 31 connected in the second chute 121 in a sliding manner, a third motor is fixedly connected to the second slide block 31, a second gear 33 is connected to an output shaft of the third motor in a key manner, and a second rack 34 meshed with the second gear 33 is fixedly connected to the side wall of the second chute 121; the second slider 31 is fixedly connected with a first connecting block 32, and the first connecting block 32 is provided with a detection component 35.

Referring to fig. 4 and 5, the detecting assembly 35 includes a magnet block 351, the magnet block 351 is adhered to the first connecting block 32, a second connecting block 352 is fixedly connected to the magnet block 351, a second groove 3521 is formed on the second connecting block 352, and a third connecting block 353 is disposed in the second groove 3521; a first threaded hole communicated with the second groove 3521 is formed in the second connecting block 352, a first bolt 355 is connected with the first threaded hole in an internal thread mode, and the first bolt 355 abuts against the third connecting block 353; a sliding hole is formed in the third connecting block 353, a test rod 356 is connected in the sliding hole in a sliding mode, one end of the test rod 356 penetrates through the sliding hole, a fourth connecting block 354 is fixedly connected to the test rod 356 penetrating through the sliding hole, and a ball 358 abutting against a window is rotatably connected to the fourth connecting block 354; the test rod 356 is sleeved with a spring 357, one end of the spring 357 is connected with the fourth connecting block 354, and the other end of the spring 357 is connected with the third connecting block 353; a third sensor is provided on the end of the test rod 356 within the slide hole.

When the window needs to be tested in a strong wind condition, the window is placed in the testing area, the third motor is started according to the height of the window, the output shaft of the third motor drives the second gear 33 to rotate, and because the second gear 33 is meshed with the second rack 34, when the second gear 33 rotates, the second gear 33 can move relative to the second rack 34, and the second gear 33 can drive the second sliding block 31 to slide in the second sliding groove 121; then at a different location where magnet block 351 was adhered to first connecting block 32; then, the cover 12 is connected to the first body 11, so that the balls 358 abut against the window; then, strong wind is introduced into the test area where the window is placed, when the window deforms, the ball 358 drives the fourth connecting block 354 to move towards the direction close to the third connecting block 353, and the test rod 356 slides in the sliding hole.

Referring to fig. 1 and 6, a fixing mechanism 5 connected to the cover 12 is disposed on the first body 11, the fixing mechanism 5 includes a fixing block 51 fixedly connected to the first body 11, a third groove 511 is disposed on the fixing block 51, a fixing rod 52 is slidably connected to the third groove 511, and an end of the fixing rod 52 far away from the third groove 511 is connected to the cover 12. A first adjusting component 53 is arranged on the fixed block 51, the first adjusting component 53 comprises a fourth motor 531 fixedly connected to the fixed block 51, and an output shaft of the fourth motor 531 drives a third gear 532; a third rack 533 engaged with the third gear 532 is fixedly connected to the fixing rod 52.

When the fourth motor 531 is started, the output shaft of the fourth motor 531 drives the third gear 532 to rotate, the third rack 533 engaged with the third gear 532 drives the fixing rod 52 to move, and the fixing rod 52 drives the cover 12 to move toward the direction close to the first body 11.

Referring to fig. 1 and 7, the second detecting device 6 includes a second main body 61, a partition wall 62 is fixedly connected in the second main body 61, the partition wall 62 divides the second main body 61 into a hot bin and a cold bin, a placing hole for placing a window is formed in the partition wall 62, and the placing hole is communicated with the hot bin and the cold bin; the cross-sectional area of the placing hole is larger than that of the window, the inner side wall of the placing hole is connected with a heat-insulating plate 64 which is abutted against the window, and the heat-insulating plate 64 and the window jointly seal the placing hole; glass cement is filled between the heat insulation plate 64 and the side wall of the placing hole, between the heat insulation plate 64 and the window and between the window and the placing hole. A baffle 63 is positioned at one end of the hot box near the dividing wall 62.

A connecting mechanism 7 is arranged in the hot bin, the connecting mechanism 7 comprises a sixth connecting block 78 fixedly connected to the upper end of the second main body 61, the sixth connecting block 78 is positioned between the guide plate 63 and the partition wall 62, and the sixth connecting block 78 is rotatably connected with a first rotating shaft 71; a second adjusting assembly 76 is arranged on the second main body 61, the second adjusting assembly 76 comprises a fifth motor 763 fixedly connected to the second main body 61, and a fourth gear 761 is keyed on an output shaft of the fifth motor 763; a fifth gear 762 meshing with the fourth gear 761 is keyed to the first shaft 71.

Referring to fig. 7 and 8, a winding disc 72 is fixedly connected to the first rotating shaft 71, and an annular groove is formed on the winding disc 72; the winding disc 72 is connected with a connecting rope 74, the connecting rope 74 can be wound in the annular groove, one end, far away from the winding disc 72, of the connecting rope 74 is fixedly connected with a seventh connecting block 79, and a fourth sensor is arranged on the seventh connecting block 79. In this embodiment, the number of the winding disks 72 is three, and the cross-sectional areas of the three winding disks 72 are gradually increased along one end far away from the fifth gear 762; the length of the connecting cord 74 on the three winding disks 72 becomes gradually longer in the direction away from the fifth gear 762.

Fixedly connected with supporting shoe 73 on the rolling dish 72 lateral wall, rotate on the supporting shoe 73 and be connected with the second pivot, fixed connection has limiting rod 75 on the second pivot, and limiting rod 75 contradicts the connection rope 74 that is located the ring channel, will connect rope 74 and inject in the ring channel. A third adjusting component 77 is arranged on the supporting block 73, the third adjusting component 77 comprises a sixth motor 773 fixedly connected to the supporting block 73, and an output shaft of the sixth motor 773 is in keyed connection with a sixth gear 771; a seventh gear 772 engaged with the sixth gear 771 is splined on the second rotating shaft.

When the heat insulation performance of the window is needed, the window is placed in the placing hole of the partition wall 62, and then the heat insulation plate 64 is connected to the side wall of the placing hole and the side wall of the placing hole, so that the heat insulation plate 64 and the window seal the placing hole together; and sealant is filled between the heat insulation plate 64 and the side wall of the placing hole, between the heat insulation plate 64 and the window and between the window and the placing hole for sealing.

When the fifth motor 763 is started, the output shaft of the fifth motor 763 drives the fourth gear 761 to rotate, the fifth gear 762 engaged with the fourth gear 761 drives the first rotating shaft 71 to rotate, and the first rotating shaft 71 drives the winding disc 72 to rotate.

Then, the sixth motor 773 on the winding disc 72 with the largest cross-sectional area is started first, the output shaft of the sixth motor 773 drives the sixth gear 771 to rotate, the seventh gear 772 meshed with the sixth gear 771 rotates, the seventh gear 772 drives the second rotating shaft to rotate, the second rotating shaft drives the limiting rod 75 to move, the limiting rod 75 does not interfere with the connecting rope 74 any more, the connecting rope 74 on the winding disc 72 with the largest cross-sectional area can be wound out of the annular groove when the first rotating shaft 71 rotates, and the connecting ropes 74 on the other two winding discs 72 cannot be wound out of the annular groove; after the first rotating shaft 71 rotates for a certain time, the sixth motor 773 on the intermediate winding disc 72 is started to wind the connecting rope 74 on the intermediate winding disc 72; finally, the sixth motor 773 on the winding disc 72 with the smallest cross-sectional area is started to wind out the connecting rope 74 on the winding disc 72 with the smallest cross-sectional area; finally, the ends of the three seventh connecting blocks 79, which are far away from the first rotating shaft 71, are located at different heights of the window, and finally, the fourth sensors corresponding to different heights of the window are realized.

Referring to fig. 1 and 9, the transfer device 8 includes a cart 81, a hydraulic cylinder is fixedly connected to the cart 81, a lifting table 82 is connected to a piston rod of the hydraulic cylinder, a third sliding groove 821 is formed in one side of the lifting table 82 away from the hydraulic cylinder, clamping blocks 83 are connected to both ends of the third sliding groove 821 in a sliding manner, and the two clamping blocks 83 form a clamping space. A fourth adjusting assembly 84 is arranged on the lifting platform 82, the fourth adjusting assembly 84 comprises a bidirectional screw 841 rotatably connected in the third sliding chute 821, the thread directions of two ends of the bidirectional screw 841 are opposite, the bidirectional screw 841 penetrates through two clamping blocks 83, and the two clamping blocks 83 are respectively in threaded connection with two ends of the bidirectional screw 841; a seventh motor 842 connected with the bidirectional screw 841 is fixedly connected to the lifting platform 82.

When the window is transferred, firstly, the hydraulic cylinder is started according to the size of the window, so that the position of the lifting platform 82 is changed, then the window is placed in the clamping space between the two clamping blocks 83, then the seventh motor 842 is started, the output shaft of the seventh motor 842 drives the two-way screw 841 to rotate, the two-way screw 841 drives the two clamping blocks 83 to move oppositely, and the two clamping blocks 83 clamp the window; the cart 81 is then pushed to transfer the window from the first body 11 into the first body 11.

The motors in this embodiment are all three-phase asynchronous motors.

The implementation principle of the window detection equipment in the embodiment of the application is as follows: when a larger window needs to be detected, or two windows with different sizes need to be detected, the position of the partition plate is adjusted; then, the window is installed in the test zone, and then the first sealing plate 41 is attached to the first body 11, the second sealing plate 42 is determined according to the size of the window, and the second sealing plate 42 is attached to the first body 11 such that the second sealing plate 42, the second sealing plate 42 and the window seal the placement zone of the first body 11; the connection of two adjacent first sealing plates 41 and the connection of the first sealing plate 41 and the second sealing plate 42 are realized by a connecting assembly 43; finally, the first sealing plate 41, the second sealing plate 42 and the window are aligned by the fixing assembly 44.

When the air outlet air-out was normal, the condition of the normal weather of simulation, the gas permeability of first sensor detection window glass department. When the air outlet volume is large, the windy weather is simulated, and the deflection of the window is detected by the third sensor. The outlet pipe goes out water, the condition of the weather of simulation rainy, and the second sensor detects whether leak when the window is rainy.

After the detection is completed, the window is detached from the first body 11, and then placed on the lifting platform 82, and the window is transported into the second body 61 by the cart 81 to perform the detection of the thermal insulation performance of the window.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (7)

1. A window detecting apparatus, characterized in that it comprises a first detecting device (1), a second detecting device (6) and a transferring device (8), said second detecting device (6) being arranged at one side of said first detecting device (1), said transferring device (8) transferring windows from said first detecting device (1) to said second detecting device (6); the first detection device (1) comprises a first main body (11), a water outlet pipe, an air outlet pipe, a cover body (12), a first sensor, a second sensor, a third sensor, a deflection detection mechanism (3) and a division mechanism (2), wherein a placing area is formed on the first main body (11), and the water outlet pipe and the air outlet pipe are both arranged in the first main body (11); the dividing mechanism (2) is arranged in the first main body (11), and the dividing mechanism (2) divides the placing area into different testing areas; the cover body (12) is connected with the first main body (11), the deflection detection mechanism (3) is arranged on the cover body (12), the first sensor and the second sensor are both arranged on the cover body (12), and the third sensor is arranged on the deflection detection mechanism (3);

A first sliding groove is formed in the upper end of the first main body (11), the dividing mechanism (2) comprises a first sliding block (21), a dividing plate, a first screw rod (22) and a first motor (23), the first sliding block (21) is connected in the first sliding groove in a sliding mode, and the first screw rod (22) is arranged in the first sliding groove and connected with the first sliding block (21); the first motor (23) is arranged on the first main body (11) and is connected with the first screw rod (22);

the placing area is divided into different testing areas by the partition plate, the partition plate comprises a main plate (241), an auxiliary plate (242), an adjusting rod (243), a second motor (244), a first gear (245) and a first rack (246), the main plate (241) is connected with the first sliding block (21), a first groove (2411) is formed in the main plate (241), the auxiliary plate (242) is connected in the first groove (2411) in a sliding mode, the auxiliary plate (242) abuts against the side wall of the first main body (11), the adjusting rod (243) is arranged on the auxiliary plate (242), and the first rack (246) is arranged on the adjusting rod (243); the second motor (244) is arranged on the main plate (241), and the first gear (245) is connected to an output shaft of the second motor (244) in a key mode and meshed with the first rack (246).

2. A window testing device according to claim 1, characterized in that the cross-sectional area of the test area is larger than the cross-sectional area of the window, and that the first body (11) is provided with a connecting plate (4), which connecting plate (4) together with the window covers the placement area;

a second sliding groove (121) is formed in the cover body (12), the deflection detection mechanism (3) comprises a second sliding block (31), a first connecting block (32), a third motor, a second gear (33), a second rack (34) and a detection assembly (35), the second sliding block (31) is connected in the second sliding groove (121) in a sliding mode, the third motor is arranged on the second sliding block (31), and the second gear (33) is connected to an output shaft of the third motor in a key mode; the second rack (34) is arranged on the side wall of the second sliding chute (121) and is meshed with the second gear (33);

the first connecting block (32) is arranged on the second sliding block (31);

the detection assembly (35) comprises a magnet block (351), a second connecting block (352), a third connecting block (353), a fourth connecting block (354), a first bolt (355), a test rod (356), a spring (357) and a ball (358), the magnet block (351) is connected with the first connecting block (32), the second connecting block (352) is arranged on the magnet block (351), a second groove (3521) is formed in the second connecting block (352), and the third connecting block (353) is arranged in the second groove (3521); a first threaded hole is formed in the second connecting block (352), and the first bolt (355) is in threaded connection with the first threaded hole and abuts against the third connecting block (353); a sliding hole is formed in the third connecting block (353), the testing rod (356) is connected in the sliding hole in a sliding mode, and the third sensor is arranged on the testing rod (356); the fourth connecting block (354) is arranged on the testing rod (356), and the rolling ball (358) is arranged on the fourth connecting block (354) and abuts against a window; the spring (357) is sleeved on the test rod (356), one end of the spring (357) is connected with the third connecting block (353) and the other end of the spring is connected with the fourth connecting block (354).

3. A window testing apparatus according to claim 2, wherein said connection plate (4) comprises a first sealing plate (41) and a second sealing plate (42), said first sealing plate (41) being provided at an upper end of said first body (11), said second sealing plate (42) being connected to said first sealing plate (41), said second sealing plate (42), said first sealing plate (41) and the window sealing said placement area;

a connecting assembly (43) is arranged between the first sealing plate (41) and the second sealing plate (42), the connecting assembly (43) comprises a fifth connecting block (431) and a second bolt (432), one end of the fifth connecting block (431) abuts against the second sealing plate (42), the other end of the fifth connecting block (431) is provided with a second threaded hole, the second bolt (432) is in threaded connection with the second threaded hole, and the second bolt (432) penetrates through the second threaded hole and abuts against the first sealing plate (41);

a fixing component (44) is arranged on the first main body (11), the fixing component (44) comprises an adjusting block (441), a fixing plate (442), a third bolt (443) and a fourth bolt (444), a first through hole is formed in the adjusting block (441), a third threaded hole is formed in the first main body (11), and the third bolt (443) penetrates through the first through hole and is in threaded connection with the third threaded hole; a fourth threaded hole is formed in the adjusting block (441), the fourth bolt (444) is in threaded connection with the fourth threaded hole, the fixing plate (442) is connected with the fourth bolt (444), and the fixing plate (442) abuts against the first sealing plate (41), the second sealing plate (42) and the window.

4. The window detecting apparatus according to claim 1, wherein the first body (11) is provided with a fixing mechanism (5) connected to the cover (12), the fixing mechanism (5) comprises a fixing block (51), a fixing rod (52) and a first adjusting component (53), the fixing block (51) is disposed on the first body (11), and the fixing block (51) is provided with a third groove (511); one end of the fixing rod (52) is connected in the third groove (511) in a sliding manner, and the other end of the fixing rod is connected with the cover body (12);

the first adjusting component (53) comprises a fourth motor (531), a third gear (532) and a third rack (533), the fourth motor (531) is arranged on the fixed block (51), and the third gear (532) is connected to an output shaft of the fourth motor (531) in a key mode; the third rack (533) is disposed on the fixing lever (52) and engaged with the third gear (532).

5. The window detecting apparatus according to claim 1, wherein the second detecting device (6) comprises a second main body (61), a partition wall (62), a flow guide plate (63), a heat insulation plate (64) and a fourth sensor, the partition wall (62) is arranged in the second main body (61), the partition wall (62) divides the second main body (61) into a cold bin and a hot bin, a placing hole for placing a window is formed in the partition wall (62), and the placing hole is communicated with the cold bin and the hot bin; the cross section area of the placing hole is larger than that of the window, and a heat insulation plate (64) abutting against the window is arranged on the side wall of the placing hole;

The deflector (63) is arranged on one side of the hot bin close to the dividing wall (62), and the fourth sensor is positioned between the dividing wall (62) and the deflector (63).

6. A window detecting device according to claim 5, characterized in that a connecting mechanism (7) is arranged in the hot bin, the connecting mechanism (7) comprises a first rotating shaft (71), a second rotating shaft, a winding disc (72), a connecting rope (74), a limiting rod (75), a second adjusting component (76) and a third adjusting component (77), the first rotating shaft (71) is arranged on the second main body (61), the second rotating shaft is positioned between the deflector (63) and the partition wall (62), the winding disc (72) is arranged on the second rotating shaft, the connecting rope (74) is connected with the winding disc (72), and the fourth sensor is connected with the connecting rope (74);

the second rotating shaft is arranged on the winding disc (72), and the limiting rod (75) is arranged on the second rotating shaft and abuts against a connecting rope (74) on the winding disc (72);

the second adjusting assembly (76) comprises a fourth gear (761), a fifth gear (762) and a fifth motor (763), the fifth motor (763) is arranged on the second body (61), the output shaft of the fifth motor (763) is keyed with the fourth gear (761), the first rotating shaft (71) is keyed with the fifth gear (762) engaged with the fourth gear (761);

The third adjusting assembly (77) comprises a sixth gear (771), a seventh gear (772) and a sixth motor (773), the sixth motor (773) is arranged on the take-up reel (72), and the sixth gear (771) is keyed on the sixth motor (773); the seventh gear (772) is keyed on the second shaft and meshes with the sixth gear (771).

7. The window detection equipment according to claim 1, wherein the transfer device (8) comprises a trolley (81), a hydraulic cylinder, a lifting platform (82), a clamping block (83) and a fourth adjusting component (84), the hydraulic cylinder is arranged on the trolley (81), the lifting platform (82) is arranged on a piston rod of the hydraulic cylinder, a third sliding groove (821) is formed in the lifting platform (82), and the clamping block (83) is connected to two ends of the third sliding groove (821) in a sliding manner;

the fourth adjusting assembly (84) comprises a bidirectional screw (841) and a seventh motor (842), the bidirectional screw (841) is rotatably connected in the third sliding groove (821), and the two clamping blocks (83) are respectively connected with two ends of the bidirectional screw (841); the seventh motor (842) is arranged on the lifting platform (82) and is connected with the bidirectional screw (841).

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