CN116924669A - Homogenizing furnace for toughened glass - Google Patents

Abstract

The invention discloses a homogenizing furnace for toughened glass, and in particular relates to the technical field of toughened glass processing equipment. According to the homogenizing furnace for toughened glass, the glass can be clamped and fixed by the aid of the first clamping device and the second clamping device, so that the glass is prevented from moving in the homogenizing process, poor homogenizing effect is caused, the glass can be intermittently rotated by 180 degrees through the intermittent device, the scraping assembly is driven to work, and the linkage assembly and the reciprocating device are driven to reciprocate up and down.

Description

Homogenizing furnace for toughened glass

Technical Field

The invention relates to the technical field of toughened glass processing equipment, in particular to a homogenizing furnace for toughened glass.

Background

The toughened glass homogenizing furnace is detection equipment for finished products of toughened glass, enters the homogenizing furnace after the glass tempering process is finished, performs detonation test and eliminates residual nickel sulfide by a hot dipping principle of the homogenizing furnace, and detonates the toughened glass with 'self-explosion' hidden danger, namely nonuniform internal stress of the glass, in advance in the test process, so that 'self-explosion' is avoided again after the toughened glass is installed, the qualified rate of the toughened glass after homogenization is greatly improved, and the safety and reliability of the toughened glass of a building are improved.

The existing toughened glass homogenizing furnace simply heats toughened glass through internal heating, is heated unevenly, influences the heating effect and quality of the toughened glass, and cannot fix the glass, so that the toughened glass is uniformly heated after being fixed, the homogenizing effect of the toughened glass is better, and the quality of the toughened glass is better.

Chinese patent document CN114199940a discloses a homogenizing furnace for toughened glass, comprising a furnace body, further comprising: one end of the circulating air draft mechanism is connected with the furnace body, and the other end of the circulating air draft mechanism is communicated with the inside of the furnace body; the device comprises a furnace body, a circulating air draft mechanism, a turbulent flow mechanism, a fixing mechanism, a uniform heating mechanism, a fixing mechanism and a turbulent flow mechanism, wherein one end of the uniform heating mechanism is connected with the circulating air draft mechanism, the other end of the uniform heating mechanism is connected with the furnace body, the turbulent flow mechanism is connected with the uniform heating mechanism, the fixing mechanism is used for fixing toughened glass, the uniform heating mechanism is used for guaranteeing that the toughened glass is uniformly heated, the turbulent flow mechanism is used for disturbing hot air in the furnace body, the circulating air draft mechanism is used for fixing the toughened glass in the furnace body, and the uniform heating mechanism is used for guaranteeing that the toughened glass is uniformly heated;

this patent is when in actual use, although can fix glass, guaranteed toughened glass and heated uniformly simultaneously, but probably contain impurity in the air of suction, impurity can block up into the tuber pipe to lead to wind can not enter into in the cavity, thereby lead to the device unable to continue to use.

Disclosure of Invention

The invention mainly aims to provide a homogenizing furnace for toughened glass, which can effectively solve the problem that impurities in air can block an air inlet.

In order to achieve the above purpose, the technical scheme adopted by the invention is as follows:

the utility model provides a toughened glass is with homogeneity stove, includes places casing and two fixed plates, place the casing rear portion and be equipped with the baffle, baffle rear end right part is equipped with the handle, place the inside homogeneity chamber that is equipped with of casing, homogeneity chamber bottom left and right sides all is equipped with first clamping device, two the fixed plate all with place casing fixed connection, place the casing upper end left and right sides all is equipped with synchronizer, two the one side that synchronizer lower extreme is close to each other all is equipped with second clamping device, two second clamping device is the same with two first clamping device structures;

the synchronous device comprises an intermittent device and a scraping assembly, the intermittent device is connected with the scraping assembly in a winding manner, the scraping assembly is connected with the heating assembly in a sliding manner, a linkage assembly is arranged at the lower end of the scraping assembly, a reciprocating device is arranged at the lower end of the linkage assembly, and the reciprocating device is connected with the fixing plate in a sliding manner.

Preferably, the heating element comprises a heating shell, a heating cavity is arranged in the heating shell, a first filter plate is arranged at the upper part and the lower part of the heating cavity, a connecting frame is arranged at the middle part of the heating cavity, heating wires are arranged on the inner surface of the connecting frame, a plurality of air inlet pipes are arranged at the upper end of the heating shell, a main pipe is arranged at the upper end of each air inlet pipe, a connecting pipe is arranged at the front part of the outer surface of the main pipe, and the connecting pipe is connected with a blower.

Preferably, the first clamping device comprises a mounting plate and two supporting blocks, wherein the mounting plate is fixedly connected with the two supporting blocks, a sliding block is arranged at one end, close to each other, of each supporting block, an adjusting component is arranged in the middle of the sliding block, and driven components are arranged at the left side and the right side of the adjusting component.

Preferably, the adjusting component comprises a threaded rod and a rotating plate, the threaded rod is in threaded connection with the sliding block, the threaded rod is fixedly connected with the rotating plate, one end, far away from the rotating plate, of the threaded rod is provided with the sliding plate, sliding grooves are formed in the left side and the right side of the sliding plate, the directions of the sliding grooves are opposite, and the sliding grooves are in sliding connection with the driven component.

Preferably, the driven component comprises a sliding column, the sliding column is in sliding connection with a sliding groove on the same side, a supporting plate is arranged at the front end of the sliding column, a first slideway is arranged on the outer surface of the supporting plate, the first slideway is fixedly connected with a sliding block, and a clamping block is arranged at one end, far away from the placing shell, of the supporting plate.

Preferably, the intermittent device comprises a motor, a top plate is arranged at the upper end of the motor, a main shaft is arranged at the output end of the motor, a first belt pulley is arranged on the upper portion of the outer surface of the main shaft, and an intermittent assembly is arranged on the lower portion of the outer surface of the main shaft.

Preferably, the intermittent assembly comprises an intermittent block, the main shaft is fixedly connected with the intermittent block, a driven plate is arranged at the upper end of the intermittent block, a limiting block is arranged on the outer surface of the driven plate, the limiting block is fixedly connected with the placing shell, intermittent columns are arranged on the front side and the rear side of the lower end of the driven plate, and a bearing plate is arranged at the lower ends of the intermittent columns.

Preferably, the scraping assembly comprises a second belt pulley and a scraping plate, the second belt pulley is connected with the first belt pulley in a winding manner, a reciprocating plate is arranged at the upper end of the second belt pulley, a supporting column is arranged at the lower end of the second belt pulley, a reciprocating column is arranged at one side, far away from the second belt pulley, of the upper end of the reciprocating plate, a limiting plate is arranged on the outer surface of the reciprocating column, a reciprocating rod is arranged at one end, far away from the second belt pulley, of the limiting plate, a driving rod is arranged at one side, far away from the limiting plate, of the upper end of the reciprocating rod, a limiting plate is arranged on the outer surface of the driving rod, the limiting plate is fixedly connected with a top plate, and a fixing block is arranged on the outer surface of the reciprocating rod.

Preferably, the linkage assembly comprises a linkage column, a first rack and a second rack, the linkage column is fixedly connected with the reciprocating rod, the linkage column is fixedly connected with the first rack, a third slide way is arranged on the outer surface of the first rack, bearing blocks are arranged on the left side and the right side of the lower end of the third slide way, a first gear is arranged on the upper portion of the outer surface of the first rack, a linkage shaft is arranged at the rear end of the first gear, a second gear is arranged at the rear end of the linkage shaft, a bearing block is arranged on the outer surface of the linkage shaft, the second rack is meshed with the second gear, and a second slide way is arranged on the outer surface of the second rack.

Preferably, the reciprocating device comprises a vertical plate and a hose, the vertical plate is fixedly connected with a second rack, the lower end of the second rack is provided with a connecting plate, the upper and lower parts of one end of the connecting plate, which is far away from the placing shell, are respectively provided with a blowing head, two ends of the blowing heads, which are close to one end of the placing shell, are respectively provided with a branch pipe, two ends of the branch pipes, which are far away from the connecting plate, are jointly provided with a fixed pipe, the fixed pipe is communicated with the hose, the rear end of the hose is provided with an induced draft pump, the output end of the induced draft pump is provided with a communicating pipe, and the communicating pipe is communicated with the heating assembly.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the glass can be clamped and fixed by the aid of the first clamping device and the second clamping device, so that the glass is prevented from moving in the homogenizing process, the homogenizing effect is poor, the two driven assemblies can be moved by the aid of the adjusting assemblies, the glass is clamped and fixed, the glass is prevented from moving in the homogenizing process, and the quality of the glass is finally affected.

2. According to the invention, the intermittent device is arranged to enable the glass to intermittently rotate at 180 degrees, the scraping component is driven to work when the intermittent device works, the scraping component is arranged to scrape impurities on the upper surface of the first filter plate at the upper part, the linkage component and the reciprocating device are driven to reciprocate up and down when the scraping component works, so that hot air is uniformly blown on one side of the glass, multiple functions are realized, when the glass intermittently rotates at 180 degrees, impurities on the upper surface of the first filter plate are scraped, and the hot air is blown to different positions on one side of the glass, so that the glass is uniformly heated, and finally the glass quality is better.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic plan view of the present invention;

FIG. 4 is a schematic view of a heating assembly according to the present invention;

FIG. 5 is a schematic view of a first clamping device according to the present invention;

FIG. 6 is a schematic view of an adjustment assembly and a driven assembly according to the present invention;

FIG. 7 is a schematic diagram of a synchronous device according to the present invention;

FIG. 8 is a schematic diagram of a batch device configuration of the present invention;

FIG. 9 is a schematic view of an intermittent assembly structure of the present invention;

FIG. 10 is a schematic view of a scraping assembly of the present invention;

FIG. 11 is a schematic view of a linkage assembly of the present invention;

fig. 12 is a schematic view of the structure of the reciprocating device of the present invention.

In the figure: 1. placing a shell; 2. a baffle; 3. a handle; 4. a heating assembly; 5. a synchronizing device; 6. a first clamping device; 7. a homogenizing chamber; 8. a fixing plate; 9. a second clamping device; 40. a heating housing; 41. a first filter plate; 42. an air inlet pipe; 43. a main pipe; 44. a connecting pipe; 45. a connection frame; 46. a heating wire; 47. a heating chamber; 60. a mounting plate; 61. a support block; 62. a sliding block; 63. an adjustment assembly; 64. a driven assembly; 630. a rotating plate; 631. a threaded rod; 632. a sliding plate; 633. a sliding groove; 640. a sliding column; 641. a support plate; 642. a first slideway; 643. a clamping block; 50. an intermittent device; 51. a scraping assembly; 52. a linkage assembly; 53. a reciprocating device; 500. a top plate; 501. a motor; 502. a first pulley; 503. a main shaft; 504. an intermittent assembly; 5040. intermittent blocks; 5041. a driven plate; 5042. a batch column; 5043. a limiting block; 5044. a receiving plate; 510. a second pulley; 511. a support column; 512. a shuttle plate; 513. a reciprocating column; 514. a reciprocating lever; 515. a fixed block; 516. a drive rod; 517. a limiting plate; 518. a scraping plate; 520. a linkage column; 521. a second slideway; 522. a first rack; 523. a third slideway; 524. a bearing block; 525. a first gear; 526. a receiving block; 527. a second gear; 528. a linkage shaft; 529. a second rack; 530. a riser; 531. a connecting plate; 532. a blowing head; 533. a fixed tube; 534. a branch pipe; 535. a hose; 536. an induced draft pump; 537. and communicating pipe.

Detailed Description

The invention is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

Example 1

1-6, a homogenizing furnace for toughened glass comprises a placing shell 1 and two fixing plates 8, wherein a baffle plate 2 is arranged at the rear part of the placing shell 1, a handle 3 is arranged at the right part of the rear end of the baffle plate 2, a homogenizing cavity 7 is arranged in the placing shell 1, first clamping devices 6 are respectively arranged at the left side and the right side of the bottom of the homogenizing cavity 7, the two fixing plates 8 are fixedly connected with the placing shell 1, synchronous devices 5 are respectively arranged at the left side and the right side of the upper end of the placing shell 1, as shown in FIG. 3, second clamping devices 9 are respectively arranged at one side, close to each other, of the lower ends of the two synchronous devices 5, and the two second clamping devices 9 and the two first clamping devices 6 have the same structure;

before homogenizing the toughened glass, the handle 3 is pulled, so that the baffle plate 2 is opened, then the two toughened glass is fixedly clamped by the two second clamping devices 9 and the two first clamping devices 6, so that the toughened glass is prevented from moving during homogenizing, the homogenizing effect is affected, and meanwhile, the glass can be uniformly heated by the aid of the set synchronizing device 5, so that the homogenizing effect is better.

As shown in fig. 4, the heating assembly 4 comprises a heating housing 40, a heating cavity 47 is arranged in the heating housing 40, first filter plates 41 are arranged at the upper and lower parts of the heating cavity 47, a connecting frame 45 is arranged in the middle of the heating cavity 47, heating wires 46 are arranged on the inner surface of the connecting frame 45, a plurality of air inlet pipes 42 are arranged at the upper end of the heating housing 40, a main pipe 43 is commonly arranged at the upper ends of the plurality of air inlet pipes 42, a connecting pipe 44 is arranged at the front part of the outer surface of the main pipe 43, and the connecting pipe 44 is connected with a blower;

the connection pipe 44 is connected with the blower, so that air is sucked into the main pipe 43, and is respectively introduced into the plurality of air inlet pipes 42, and impurities are prevented from entering the inside of the placement housing 1 by falling on the upper surface of the upper first filter plate 41 due to the impurities in the air, so that the homogenizing effect is affected, and after the air passes through the first filter plate 41, the air passes through the heating wire 46, so that hot air flows out of the lower first filter plate 41, and hot air enters the inside of the placement housing 1.

As shown in fig. 5, the first clamping device 6 includes a mounting plate 60 and two supporting blocks 61, the mounting plate 60 is fixedly connected with the two supporting blocks 61, a sliding block 62 is arranged at one end of the two supporting blocks 61 close to each other, an adjusting component 63 is arranged in the middle of the sliding block 62, and driven components 64 are arranged at the left and right sides of the adjusting component 63;

the first clamping device 6 and the second clamping device 9 are identical in structure, the glass is clamped and fixed at first, the two driven assemblies 64 can be moved by the aid of the adjusting assembly 63, so that the glass is clamped and fixed, the glass is prevented from moving in the homogenizing process, and the homogenizing result is finally influenced.

Specifically, as shown in fig. 6, the adjusting component 63 includes a threaded rod 631 and a rotating plate 630, the threaded rod 631 is in threaded connection with the sliding block 62, the threaded rod 631 is fixedly connected with the rotating plate 630, one end of the threaded rod 631 away from the rotating plate 630 is provided with a sliding plate 632, the left side and the right side of the sliding plate 632 are both provided with sliding grooves 633, the directions of the two sliding grooves 633 are opposite, and the two sliding grooves 633 are both in sliding connection with the driven component 64;

the driven component 64 comprises a sliding column 640, the sliding column 640 is in sliding connection with a sliding groove 633 on the same side, a supporting plate 641 is arranged at the front end of the sliding column 640, a first slideway 642 is arranged on the outer surface of the supporting plate 641, the first slideway 642 is fixedly connected with the sliding block 62, and a clamping block 643 is arranged at one end of the supporting plate 641, which is far away from the placing shell 1;

first, the rotating plate 630 rotates the threaded rod 631, so that the sliding plate 632 slides on the inner surface of the sliding block 62, and since the two sliding grooves 633 are inclined grooves and the directions of the two sliding grooves 633 are opposite, when the sliding plate 632 moves, the sliding columns 640 on two sides slide inside the sliding grooves 633 on the same side, so that the supporting plates 641 on the left and right sides are driven to move in opposite directions, the clamping block 643 is also moved, so that glasses with different widths are clamped, and finally the applicability of the homogenizing furnace is stronger.

The specific implementation mode is as follows: first, the handle 3 is pulled to open the baffle 2, and then the rotating plate 630 is rotated to rotate the threaded rod 631, so that the sliding plate 632 slides on the inner surface of the sliding block 62, and since the two sliding grooves 633 are inclined grooves and the directions of the two sliding grooves 633 are opposite, when the sliding plate 632 moves, the sliding columns 640 on two sides slide inside the sliding grooves 633 on the same side, so that the supporting plates 641 on the left side and the right side are driven to move in opposite directions, so that the clamping block 643 also moves, and thus glasses with different widths are clamped and fixed.

Example two

In this embodiment, as shown in fig. 7-12, in order to uniformly heat glass, impurities on the upper surface of the upper first filter plate 41 can be scraped off, so as to prevent the impurities from blocking the upper first filter plate 41 and prevent wind from entering the inside of the placement housing 1.

As shown in fig. 5, the synchronizing device 5 comprises an intermittent device 50 and a scraping assembly 51, the intermittent device 50 is connected with the scraping assembly 51 in a winding way, the scraping assembly 51 is connected with the heating assembly 4 in a sliding way, a linkage assembly 52 is arranged at the lower end of the scraping assembly 51, a reciprocating device 53 is arranged at the lower end of the linkage assembly 52, and the reciprocating device 53 is connected with the fixed plate 8 in a sliding way;

the intermittent device 50 is arranged to enable the glass to intermittently rotate by 180 degrees, so that the glass is heated uniformly, the scraping component 51 is driven to work when the intermittent device 50 works, the scraping component 51 is arranged to scrape impurities on the upper surface of the first filter plate 41, and the linkage component 52 and the reciprocating device 53 are driven to reciprocate up and down when the scraping component 51 works, so that hot air is blown to one side of the glass uniformly.

In detail, referring to fig. 8, the intermittent device 50 includes a motor 501, a top plate 500 is disposed at an upper end of the motor 501, a spindle 503 is disposed at an output end of the motor 501, a first belt pulley 502 is disposed at an upper portion of an outer surface of the spindle 503, and an intermittent assembly 504 is disposed at a lower portion of an outer surface of the spindle 503;

when the motor 501 is started, the first belt pulley 502 and the main shaft 503 are moved, so that the intermittent assembly 504 is operated to drive the second clamping device 9 to rotate, and when the second clamping device 9 rotates, the lower part of the first clamping device 6 is rotationally connected with the placing shell 1, the first clamping device 6 is driven to rotate.

As shown in fig. 9, the intermittent assembly 504 includes an intermittent block 5040, a main shaft 503 is fixedly connected with the intermittent block 5040, a driven plate 5041 is arranged at the upper end of the intermittent block 5040, a limiting block 5043 is arranged on the outer surface of the driven plate 5041, the limiting block 5043 is fixedly connected with the placement housing 1, intermittent columns 5042 are arranged at the front side and the rear side of the lower end of the driven plate 5041, and a receiving plate 5044 is arranged at the lower ends of the two intermittent columns 5042 together;

the main shaft 503 and the intermittent block 5040 are eccentrically arranged, when the main shaft 503 rotates, the intermittent block 5040 fixed with the main shaft 503 rotates, and as one side of the outer surface of the intermittent block 5040 is provided with a bulge, and the driven plate 5041 is movably connected with the main shaft 503, when the intermittent block 5040 rotates, the two intermittent columns 5042 are touched, so that the receiving plate 5044 is driven to rotate, the second clamping device 9 is driven to rotate intermittently by 180 degrees, and glass is heated uniformly.

As shown in fig. 10, the scraping assembly 51 includes a second belt pulley 510 and a scraping plate 518, the second belt pulley 510 is wound and connected with the first belt pulley 502, a reciprocating plate 512 is provided at the upper end of the second belt pulley 510, a supporting column 511 is provided at the lower end of the second belt pulley 510, a reciprocating column 513 is provided at one side of the upper end of the reciprocating plate 512 far away from the second belt pulley 510, a limiting plate 517 is provided at the outer surface of the reciprocating column 513, a reciprocating rod 514 is provided at one end of the limiting plate 517 far away from the second belt pulley 510, a driving rod 516 is provided at one side of the upper end of the reciprocating rod 514 far away from the limiting plate 517, a limiting plate 517 is provided at the outer surface of the driving rod 516, the limiting plate 517 is fixedly connected with the top plate 500, the driving rod 516 is fixedly connected with the scraping plate 518, and a fixing block 515 is provided at the outer surface of the reciprocating rod 514;

when the first belt pulley 502 rotates, the second belt pulley 510 rotates, so that the reciprocating plate 512 rotates, the reciprocating column 513 slides on the inner surface of the limiting plate 517, so that the reciprocating rod 514 moves, and the second belt pulley 510 also rotates continuously due to the continuous rotation of the first belt pulley 502, so that the reciprocating rod 514 continuously reciprocates left and right, and the driving rod 516 at the upper end is driven to reciprocate left and right, and the driving rod 516 is in sliding connection with the heating assembly 4, so that the scraping plate 518 also reciprocates when the driving rod 516 reciprocates left and right, so that impurities on the upper surface of the upper first filter plate 41 are scraped, and the first filter plate 41 is prevented from being blocked by the impurities.

As shown in fig. 11, the linkage assembly 52 includes a linkage column 520, a first rack 522 and a second rack 529, the linkage column 520 is fixedly connected with the reciprocating rod 514, the linkage column 520 is fixedly connected with the first rack 522, a third slide way 523 is arranged on the outer surface of the first rack 522, bearing blocks 524 are arranged on the left side and the right side of the lower end of the third slide way 523, a first gear 525 is arranged on the upper portion of the outer surface of the first rack 522, a linkage shaft 528 is arranged at the rear end of the first gear 525, a second gear 527 is arranged at the rear end of the linkage shaft 528, a bearing block 526 is arranged on the outer surface of the linkage shaft 528, the second rack 529 is meshed with the second gear 527, and a second slide way 521 is arranged on the outer surface of the second rack 529;

when the scraping assembly 51 works and drives the linkage assembly 52 to work, the reciprocating rod 514 reciprocates left and right, so that the linkage column 520 and the second slide way 521 also reciprocate, the first gear 525 rotates, the linkage shaft 528 and the second gear 527 rotate, and the second gear 527 drives the second rack 529 to move up and down, so as to drive the reciprocating device 53 to reciprocate up and down.

As shown in fig. 12, the reciprocator 53 includes a vertical plate 530 and a hose 535, the vertical plate 530 is fixedly connected with a second rack 529, a connecting plate 531 is arranged at the lower end of the second rack 529, air blowing heads 532 are arranged at the upper and lower parts of one end of the connecting plate 531 far away from the placing shell 1, branch pipes 534 are arranged at one ends of the two air blowing heads 532 close to the placing shell 1, a fixed pipe 533 is jointly arranged at one end of the two branch pipes 534 far away from the connecting plate 531, the fixed pipe 533 is communicated with the hose 535, an air suction pump 536 is arranged at the rear end of the hose 535, a communicating pipe 537 is arranged at the output end of the air suction pump 536, and the communicating pipe 537 is communicated with the heating component 4;

when the second rack 529 reciprocates up and down, the vertical plate 530 and the connection plate 531 reciprocate up and down, so that the two blowing heads 532 reciprocate up and down, and the communicating pipe 537 is provided to communicate with the heating unit 4, so that the hot air in the heating unit 4 is drawn into the hose 535, and the hot air flows into the two branch pipes 534, and finally is ejected from the two blowing heads 532.

The specific implementation mode is as follows: to heat the glass more uniformly, the motor 501 is started to move the first pulley 502 and the main shaft 503, the intermittent block 5040 is rotated, when the intermittent block 5040 rotates, the two intermittent posts 5042 are touched, the receiving plate 5044 is rotated, the second clamping device 9 is driven to rotate 180 degrees intermittently, the glass is driven to rotate 180 degrees intermittently, meanwhile, when the first pulley 502 rotates, the second pulley 510 rotates, the reciprocating plate 512 rotates, the reciprocating post 513 slides on the inner surface of the limiting plate 517, the reciprocating rod 514 moves, the driving rod 516 and the scraping plate 518 reciprocate, impurities on the upper surface of the first filter plate 41 are scraped, when the reciprocating rod 514 moves, the linkage post 520 and the second slide 521 reciprocate, the first gear 525 rotates, the linkage shaft 528 and the second gear 527 rotate, the second gear 527 drives the second rack 529 to move up and down, the second rack 529 reciprocates up and down, the vertical plate 530 and the connecting plate 531 reciprocate up and down, the two blowing heads 532 reciprocate up and down, the communicating pipe 537 is communicated with the heating assembly 4, so that the hot air in the heating assembly 4 is pumped into the hose 535, the hot air flows into the two branch pipes 534 and finally is sprayed out from the two blowing heads 532, the synchronous device 5 can realize various functions, when the glass rotates intermittently by 180 degrees, impurities on the upper surface of the first filter plate 41 are scraped, and the hot air blows to different positions on one side of the glass, thereby making the glass heated uniformly.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a toughened glass is with homogeneity stove, includes to place casing (1) and two fixed plates (8), its characterized in that: the novel multifunctional portable ultrasonic vibration machine is characterized in that a baffle plate (2) is arranged at the rear part of the placement shell (1), a handle (3) is arranged at the right part of the rear end of the baffle plate (2), a homogenizing cavity (7) is arranged in the placement shell (1), first clamping devices (6) are arranged at the left side and the right side of the bottom of the homogenizing cavity (7), two fixing plates (8) are fixedly connected with the placement shell (1), synchronous devices (5) are arranged at the left side and the right side of the upper end of the placement shell (1), second clamping devices (9) are arranged at one sides, close to each other, of the lower ends of the synchronous devices (5), and the two second clamping devices (9) are identical to the two first clamping devices (6) in structure;

the synchronous device (5) comprises an intermittent device (50) and a scraping assembly (51), the intermittent device (50) is connected with the scraping assembly (51) in a winding mode, the scraping assembly (51) is connected with the heating assembly (4) in a sliding mode, a linkage assembly (52) is arranged at the lower end of the scraping assembly (51), a reciprocating device (53) is arranged at the lower end of the linkage assembly (52), and the reciprocating device (53) is connected with the fixing plate (8) in a sliding mode.

2. A homogenizing furnace for tempered glass as claimed in claim 1, wherein: heating element (4) are including heating casing (40), heating casing (40) inside is equipped with heating chamber (47), heating chamber (47) upper and lower part all is equipped with first filter plate (41), heating chamber (47) middle part is equipped with connecting frame (45), connecting frame (45) internal surface is equipped with heater strip (46), heating casing (40) upper end is equipped with a plurality of income trachea (42), and is a plurality of go into trachea (42) upper end and be equipped with person in charge (43) jointly, be equipped with connecting pipe (44) in front of person in charge (43) surface, connecting pipe (44) are connected with the air-blower.

3. A homogenizing furnace for tempered glass as claimed in claim 1, wherein: the first clamping device (6) comprises a mounting plate (60) and two supporting blocks (61), wherein the mounting plate (60) is fixedly connected with the two supporting blocks (61), sliding blocks (62) are arranged at one ends, close to each other, of the two supporting blocks (61), adjusting components (63) are arranged in the middle of the sliding blocks (62), and driven components (64) are arranged at the left side and the right side of each adjusting component (63).

4. A homogenizing furnace for tempered glass as claimed in claim 3, wherein: the adjusting component (63) comprises a threaded rod (631) and a rotating plate (630), the threaded rod (631) is in threaded connection with the sliding block (62), the threaded rod (631) is fixedly connected with the rotating plate (630), one end, far away from the rotating plate (630), of the threaded rod (631) is provided with a sliding plate (632), sliding grooves (633) are formed in the left side and the right side of the sliding plate (632), the directions of the sliding grooves (633) are opposite, and the sliding grooves (633) are in sliding connection with the driven component (64).

5. The homogenizing furnace for tempered glass as claimed in claim 4, wherein: the driven component (64) comprises a sliding column (640), the sliding column (640) is in sliding connection with a sliding groove (633) on the same side, a supporting plate (641) is arranged at the front end of the sliding column (640), a first slide way (642) is arranged on the outer surface of the supporting plate (641), the first slide way (642) is fixedly connected with a sliding block (62), and a clamping block (643) is arranged at one end, far away from the placing shell (1), of the supporting plate (641).

6. A homogenizing furnace for tempered glass as claimed in claim 1, wherein: the intermittent device (50) comprises a motor (501), a top plate (500) is arranged at the upper end of the motor (501), a main shaft (503) is arranged at the output end of the motor (501), a first belt pulley (502) is arranged on the upper portion of the outer surface of the main shaft (503), and an intermittent assembly (504) is arranged on the lower portion of the outer surface of the main shaft (503).

7. The homogenizing furnace for tempered glass as claimed in claim 6, wherein: intermittent type subassembly (504) are including intermittent type piece (5040), main shaft (503) and intermittent type piece (5040) fixed connection, intermittent type piece (5040) upper end is equipped with driven plate (5041), driven plate (5041) surface is equipped with stopper (5043), stopper (5043) and place casing (1) fixed connection, both sides all are equipped with intermittent type post (5042) around driven plate (5041) lower extreme, two intermittent type post (5042) lower extreme is equipped with joint board (5044) jointly.

8. The homogenizing furnace for tempered glass as claimed in claim 6, wherein: the scraping assembly (51) comprises a second belt pulley (510) and a scraping plate (518), the second belt pulley (510) is connected with the first belt pulley (502) in a winding mode, a reciprocating plate (512) is arranged at the upper end of the second belt pulley (510), a supporting column (511) is arranged at the lower end of the second belt pulley (510), a reciprocating column (513) is arranged at one side, far away from the second belt pulley (510), of the upper end of the reciprocating plate (512), a limiting plate (517) is arranged at one end, far away from the second belt pulley (510), of the limiting plate (517), a driving rod (516) is arranged at one side, far away from the limiting plate (517), of the upper end of the reciprocating rod (514), a limiting plate (517) is arranged at the outer surface of the driving rod (516), the limiting plate (517) is fixedly connected with a top plate (500), the driving rod (516) is fixedly connected with the scraping plate (518), and a fixing block (515) is arranged on the outer surface of the reciprocating rod (514).

9. The homogenizing furnace for tempered glass as claimed in claim 8, wherein: the linkage assembly (52) comprises a linkage column (520), a first rack (522) and a second rack (529), the linkage column (520) is fixedly connected with a reciprocating rod (514), the linkage column (520) is fixedly connected with the first rack (522), a third slide way (523) is arranged on the outer surface of the first rack (522), bearing blocks (524) are arranged on the left side and the right side of the lower end of the third slide way (523), a first gear (525) is arranged on the upper portion of the outer surface of the first rack (522), a linkage shaft (528) is arranged at the rear end of the first gear (525), a second gear (527) is arranged at the rear end of the linkage shaft (528), a bearing block (526) is arranged on the outer surface of the linkage shaft (528), the second rack (529) is meshed with the second gear (527), and a second slide way (521) is arranged on the outer surface of the second rack (529).

10. A homogenizing furnace for tempered glass as claimed in claim 1, wherein: the reciprocating device (53) comprises a vertical plate (530) and a hose (535), the vertical plate (530) is fixedly connected with a second rack (529), a connecting plate (531) is arranged at the lower end of the second rack (529), air blowing heads (532) are arranged at the upper and lower parts of one ends of the connecting plate (531) far away from a placing shell (1), branch pipes (534) are arranged at two ends of the air blowing heads (532) close to the placing shell (1), fixed pipes (533) are arranged at two ends of the branch pipes (534) far away from the connecting plate (531), the fixed pipes (533) are communicated with the hose (535), an air suction pump (536) is arranged at the rear end of the hose (535), a communicating pipe (537) is arranged at the output end of the air suction pump (536), and the communicating pipe (537) is communicated with a heating component (4).