CN210620604U - Homogenizing furnace reduces from explosion rate device - Google Patents

Abstract

The utility model belongs to the field of toughened glass production devices, in particular to a device for reducing the spontaneous explosion rate of a homogenizing furnace, aiming at the problem that a filter screen can be slowly attached to and blocked by dust in the long-term operation process of the prior device, and cannot keep a good ventilation and filtration state, thereby influencing the heating and cooling of toughened glass, the utility model provides a scheme, which comprises an outer furnace body, wherein one side of the outer furnace body is provided with two heating boxes, the two heating boxes are internally provided with the filter screen, one side of the heating boxes, which is far away from the outer furnace body, is fixedly provided with a telescopic hydraulic cylinder, and the output end of the telescopic hydraulic cylinder is fixedly provided with a telescopic shaft. Prevent it from being blocked by dust, and ensure the heating and cooling efficiency of the toughened glass.

Description

Homogenizing furnace reduces from explosion rate device

Technical Field

The utility model relates to a toughened glass apparatus for producing technical field especially relates to a homogeneity stove reduces from explosion rate device.

Background

The homogenizing furnace is the finished product check out test set of toughened glass, get into the homogenizing furnace after the glass tempering process is accomplished, the distribution of nickel sulfide should be even in the glass original sheet, if nickel sulfide distributes inhomogeneous can make glass produce glass spontaneous explosion when transportation extrusion vibration, through the homogenizing furnace hot dipping principle, explode the test and eliminate remaining nickel sulfide, will have "spontaneous explosion" hidden danger and explode in advance at the test procedure in toughened glass that the glass internal stress is uneven, thereby "spontaneous explosion" takes place once more after having avoided the toughened glass installation, thereby the spontaneous explosion rate of toughened glass has been reduced.

Publication No. CN208218676U discloses a modified toughened glass homogeneity stove, including outer furnace body, the welding of one side inner wall of outer furnace body has interior furnace body, and the bottom inner wall of interior furnace body has the bottom plate through the fix with screw, the bottom outer wall of bottom plate has the heat-insulating box through the fix with screw, and the inner wall of heat-insulating box has the second motor through the fix with screw, but the device is in long-term operation in-process, and the filter screen slowly can be attached to until blockking up by the dust, can't keep a good ventilation filtration state, influences toughened glass's heating and cooling, has improved space.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem that the filter screen is slowly attached to the dust until being blocked in the long-term operation process of the device in the prior art, so that a good ventilation filtering state can not be kept, the heating and cooling defects of toughened glass are influenced, and the provided homogenizing furnace reduces the spontaneous explosion rate device.

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

a device for reducing the self-explosion rate of a homogenizing furnace comprises an outer furnace body, wherein two heating boxes are arranged on one side of the outer furnace body, filter screens are arranged in the two heating boxes, a telescopic hydraulic cylinder is fixedly arranged on one side, away from the outer furnace body, of each heating box, a telescopic shaft is fixedly arranged at the output end of each telescopic hydraulic cylinder, three cleaning brushes are fixedly arranged on one side, close to the filter screens, of each telescopic shaft, one sides, away from the telescopic shafts, of the three cleaning brushes are all in contact with the filter screens, a sliding groove located above the filter screens is formed in one side, close to the telescopic shafts, of the heating boxes, the same sliding rod is fixedly arranged on the inner walls of the top side and the bottom side of the sliding groove, the telescopic hydraulic cylinders are started, the output ends of the telescopic hydraulic cylinders are stretched to drive the telescopic shafts to reciprocate from bottom to top, when the wedge-shaped rod is in contact with the L-shaped sliding rod, the wedge-shaped rod extrudes the L-shaped sliding rod to enable the L-shaped sliding rod to move downwards, and the wedge-shaped rod moves to drive the sliding column to slide on the sliding rod.

Preferably, sliding sleeve has cup jointed the traveller on the slide bar, outside the one end of traveller extended to the spout, same L type slide opening has been seted up to the top side and one side of traveller, slidable mounting has L type slide bar in the L type slide opening, outside the both ends of L type slide bar all extended to L type slide opening, the telescopic shaft was kept away from to L type slide bar one side was rotated and is installed the pull rod, the top of pull rod is rotated and is installed on one side of heating cabinet, L type slide bar removes and drives the pull rod and rotate, the pull rod rotates and stimulates L type slide bar and makes it slide in L type slide opening.

Preferably, the bottom side of traveller rotates installs the push rod, and the bottom of push rod rotates installs the bull stick, and one side of bull stick rotates installs the bracing piece, and the one end fixed mounting that the bull stick was kept away from to the bracing piece is on one side of heating cabinet, and one side fixed mounting that the telescopic shaft was kept away from to the bull stick has the striker, and the bottom of striker contacts with one side of filter screen, and the traveller slides and drives the push rod and rotate, and the push rod rotates and drives the bull stick and use the bracing piece to rotate as the center, and the bull stick rotates and drives the striker and filter.

Preferably, one side that the telescopic shaft is close to the heating cabinet is seted up flutedly, slidable mounting has the wedge pole in the recess, the one end of wedge pole extends to outside the recess and corresponding with the position of L type slide bar, the one end fixed mounting that the heating cabinet was kept away from to the wedge pole has the one end of first spring, the other end fixed mounting of first spring is on one side inner wall of recess, when telescopic shaft upward movement, the telescopic shaft removes and drives wedge pole rebound, L type slide bar extrusion wedge pole makes it slide in the recess when the bottom side of wedge pole and L type slide bar contacts, elastic deformation takes place for first spring, when wedge pole and recess phase separation, make the wedge pole reconversion under the reaction force of first spring.

Preferably, the slide bar is sleeved with a second spring, the top end of the second spring is fixedly installed on the bottom side of the sliding column, the bottom end of the second spring is fixedly installed on the inner wall of the bottom side of the sliding groove, the wedge-shaped rod moves to drive the sliding column to slide on the slide bar, and the second spring elastically deforms.

In the utility model, because the cleaning brush is arranged, the filter screen can be cleaned by moving the cleaning brush back and forth on the surface of the filter screen, so that the filter screen can keep good filtering and ventilating states;

the utility model discloses in, owing to set up the impact bar, through impact bar striking filter screen, can make the filter screen produce the vibration, prevent that it from being blockked up by the dust, guarantee toughened glass's heating and cooling efficiency.

Drawings

FIG. 1 is a schematic structural view of a device for reducing the spontaneous explosion rate of a homogenizing furnace according to the present invention;

fig. 2 is a schematic structural view of a portion a in fig. 1 of a device for reducing self-explosion rate of a homogenizing furnace according to the present invention;

fig. 3 is a schematic structural diagram of a portion a1 in fig. 2 of a device for reducing self-explosion rate of a homogenizing furnace according to the present invention;

fig. 4 is a schematic view of a overlooking structure of the device for reducing the spontaneous explosion rate of the homogenizing furnace, which is provided by the present invention, wherein a sliding column, a sliding rod and an L-shaped sliding rod are connected.

In the figure: the device comprises an outer furnace body 1, a heating box 2, a filter screen 3, a telescopic hydraulic cylinder 4, a telescopic shaft 5, a cleaning brush 6, a sliding chute 7, a sliding rod 8, a sliding column 9, a sliding hole 10L, a sliding rod 11L, a pull rod 12, a push rod 13, a rotating rod 14, a support rod 15, a striking rod 16, a groove 17 and a wedge-shaped rod 18.

Detailed Description

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

Example 1

Referring to fig. 1-4, a device for reducing the self-explosion rate of a homogenizing furnace comprises an outer furnace body 1, two heating boxes 2 are arranged on one side of the outer furnace body 1, filter screens 3 are arranged in the two heating boxes 2, a telescopic hydraulic cylinder 4 is fixedly arranged on one side of each heating box 2 away from the outer furnace body 1, a telescopic shaft 5 is fixedly arranged at the output end of each telescopic hydraulic cylinder 4, three cleaning brushes 6 are fixedly arranged on one sides of the telescopic shafts 5 close to the filter screens 3, one sides of the three cleaning brushes 6 away from the telescopic shafts 5 are contacted with the filter screens 3, a chute 7 positioned above the filter screens 3 is arranged on one side of the heating boxes 2 close to the telescopic shafts 5, the same slide bars 8 are fixedly arranged on the inner walls of the top side and the bottom side of the chute 7, the telescopic hydraulic cylinders 4 are started, the output ends of the telescopic hydraulic cylinders 4 are stretched to drive, the telescopic shaft 5 moves to drive the three cleaning brushes 6 to clean the filter screen 3, when the telescopic shaft 5 moves downwards, the telescopic shaft 5 moves to drive the wedge rod 18 to move downwards, when the wedge rod 18 is in contact with the L-shaped slide rod 11, the wedge rod 18 extrudes the L-shaped slide rod 11 to move downwards, and the wedge rod 18 moves to drive the sliding column 9 to slide on the slide rod 8.

The utility model discloses in, slide 8 and have cup jointed traveller 9, outside the one end of traveller 9 extended to spout 7, same L type slide opening 10 has been seted up to the top side and one side of traveller 9, slidable mounting has L type slide bar 11 in the L type slide opening 10, outside L type slide bar 11's both ends all extended to L type slide opening 10, L type slide bar 11 kept away from one side rotation of telescopic shaft 5 and installed pull rod 12, the top of pull rod 12 is rotated and is installed on one side of heating cabinet 2, L type slide bar 11 removes and drives pull rod 12 and rotate, pull rod 12 rotates and stimulates L type slide bar 11 to make it slide in L type slide opening 10.

The utility model discloses in, the bottom side of traveller 9 is rotated and is installed push rod 13, the bottom of push rod 13 is rotated and is installed bull stick 14, one side of bull stick 14 is rotated and is installed bracing piece 15, the one end fixed mounting that bull stick 14 was kept away from to bracing piece 15 is on one side of heating cabinet 2, one side fixed mounting that telescopic shaft 5 was kept away from to bull stick 14 has impact rod 16, the bottom of impact rod 16 contacts with one side of filter screen 3, traveller 9 slides and drives push rod 13 and rotate, push rod 13 rotates and drives bull stick 14 and use bracing piece 15 to rotate as the center, bull stick 14 rotates and drives impact rod 16 and the 3 phase separations of filter screen.

The utility model discloses in, telescopic shaft 5 is close to one side of heating cabinet 2 and has seted up recess 17, slidable mounting has wedge bar 18 in the recess 17, the one end of wedge bar 18 extends to outside recess 17 and corresponding with L type slide bar 11's position, the one end fixed mounting that heating cabinet 2 was kept away from to wedge bar 18 has the one end of first spring, the other end fixed mounting of first spring is on one side inner wall of recess 17, when telescopic shaft 5 upwards moves, telescopic shaft 5 removes and drives 18 rebound of wedge bar, L type slide bar 11 extrudees wedge bar 18 and makes it slide in recess 17 when wedge bar 18 contacts with the bottom side of L type slide bar 11, elastic deformation takes place for first spring, when wedge bar 18 and recess 17 phase separation, make 18 reconversion of wedge bar under the reaction force of first spring.

The utility model discloses in, cup jointed the second spring on the slide bar 8, the top fixed mounting of second spring is on the bottom side of traveller 9, and the bottom fixed mounting of second spring is on the bottom side inner wall of spout 7, and 18 removal of wedge pole drive travelers 9 slide on slide bar 8, and elastic deformation takes place for the second spring.

Example 2

Referring to fig. 1-4, a device for reducing the self-explosion rate of a homogenizing furnace comprises an outer furnace body 1, two heating boxes 2 are arranged on one side of the outer furnace body 1, filter screens 3 are arranged in the two heating boxes 2, a telescopic hydraulic cylinder 4 is fixedly arranged on one side of each heating box 2 away from the outer furnace body 1, a telescopic shaft 5 is fixedly arranged at the output end of each telescopic hydraulic cylinder 4, three cleaning brushes 6 are fixedly welded on one side of each telescopic shaft 5 close to the corresponding filter screen 3, one sides of the three cleaning brushes 6 away from the telescopic shafts 5 are all contacted with the corresponding filter screen 3, a chute 7 positioned above the corresponding filter screen 3 is arranged on one side of each heating box 2 close to the corresponding telescopic shaft 5, the same slide bar 8 is fixedly welded on the inner wall of the top side and the bottom side of the chute 7, the telescopic hydraulic cylinders 4 are started, the output ends of the telescopic hydraulic cylinders, the telescopic shaft 5 moves to drive the three cleaning brushes 6 to clean the filter screen 3, when the telescopic shaft 5 moves downwards, the telescopic shaft 5 moves to drive the wedge rod 18 to move downwards, when the wedge rod 18 is in contact with the L-shaped slide rod 11, the wedge rod 18 extrudes the L-shaped slide rod 11 to move downwards, and the wedge rod 18 moves to drive the sliding column 9 to slide on the slide rod 8.

The utility model discloses in, slide 8 is gone up and is slided and cup jointed traveller 9, outside the one end of traveller 9 extended to spout 7, same L type slide opening 10 has been seted up to the top side and one side of traveller 9, slidable mounting has L type slide bar 11 in the L type slide opening 10, the both ends of L type slide bar 11 all extend to outside L type slide opening 10, one side that telescopic shaft 5 was kept away from to L type slide bar 11 is rotated through the round pin axle and is installed pull rod 12, the top of pull rod 12 is rotated through the round pin axle and is installed on one side of heating cabinet 2, L type slide bar 11 removes and drives pull rod 12 and rotates, pull rod 12 rotates and stimulates L type slide bar 11 to make it slide in L type slide opening 10.

The utility model discloses in, push rod 13 is installed through the round pin axle rotation to the bottom side of traveller 9, bull stick 14 is installed through the round pin axle rotation to the bottom of push rod 13, bracing piece 15 is installed through the round pin axle rotation to one side of bull stick 14, the fixed welding of one end of bull stick 14 is kept away from to bracing piece 15 is on one side of heating cabinet 2, one side fixed welding that telescopic shaft 5 was kept away from to bull stick 14 has impact rod 16, the bottom of impact rod 16 contacts with one side of filter screen 3, traveller 9 slides and drives push rod 13 and rotate, push rod 13 rotates and drives bull stick 14 and uses bracing piece 15 to rotate as the center, bull stick 14 rotates and drives impact rod 16 and the 3 phase.

The utility model discloses in, telescopic shaft 5 is close to one side of heating cabinet 2 and has seted up recess 17, slidable mounting has wedge bar 18 in recess 17, wedge bar 18's one end extends to outside recess 17 and corresponding with L type slide bar 11's position, wedge bar 18 keeps away from the one end fixed welding of heating cabinet 2's one end of first spring, the other end fixed welding of first spring is on one side inner wall of recess 17, when telescopic shaft 5 upwards moves, telescopic shaft 5 removes and drives wedge bar 18 rebound, L type slide bar 11 extrudees wedge bar 18 and makes it slide in recess 17 when wedge bar 18 contacts with L type slide bar 11's bottom side, elastic deformation takes place for first spring, when wedge bar 18 and recess 17 phase separation, make wedge bar 18 reconversion under the reaction force of first spring.

The utility model discloses in, cup jointed the second spring on the slide bar 8, the fixed welding in top of second spring is on the bottom side of traveller 9, and the bottom mounting welding of second spring is on the bottom side inner wall of spout 7, and 18 removal of wedge pole drive travelers 9 slide on slide bar 8, and elastic deformation takes place for the second spring.

In the utility model, when the device is operated, the telescopic hydraulic cylinder 4 is started, the output end of the telescopic hydraulic cylinder 4 is stretched to drive the telescopic shaft 5 to do reciprocating motion first and then last, the telescopic shaft 5 moves to drive the three cleaning brushes 6 to clean the filter screen 3, when the telescopic shaft 5 moves downwards, the telescopic shaft 5 moves to drive the wedge rod 18 to move downwards, when the wedge rod 18 contacts with the L-shaped slide rod 11, the wedge rod 18 extrudes the L-shaped slide rod 11 to move downwards, the wedge rod 18 moves to drive the slide column 9 to slide on the slide rod 8, the second spring generates elastic deformation, the slide column 9 slides to drive the push rod 13 to rotate, the push rod 13 rotates to drive the rotating rod 14 to rotate by taking the support rod 15 as the center, the rotating rod 14 rotates to drive the impact rod 16 to be separated from the filter screen 3, meanwhile, the L-shaped slide rod 11 moves to drive the pull rod 12 to rotate, the pull rod 12 rotates to pull the L-, when the L-shaped sliding rod 11 slides, the L-shaped sliding rod 11 is slowly separated from the wedge-shaped rod 18, when the L-shaped sliding rod 11 is completely separated from the wedge-shaped rod 18, the sliding column 9 slides to drive the push rod 13 and the rotating rod 14 to reversely rotate, the rotating rod 14 rotates to drive the impact rod 16 to impact the filter screen 3, when the telescopic shaft 5 moves upwards, the telescopic shaft 5 moves to drive the wedge-shaped rod 18 to move upwards, when the wedge-shaped rod 18 is in contact with the bottom side of the L-shaped sliding rod 11, the L-shaped sliding rod 11 extrudes the wedge-shaped rod 18 to enable the wedge-shaped rod 18 to slide in the groove 17, the first spring elastically deforms, when the wedge-shaped rod 18 is separated from the groove 17, the wedge-shaped rod 18 is restored under the reactive force of the first spring, and at the telescopic shaft 5 continues to move upwards until.

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

Claims (5)

1. The utility model provides a homogeneity stove reduces from explosion rate device, includes outer furnace body (1), one side of outer furnace body (1) is equipped with two heater boxes (2), all is equipped with filter screen (3) in two heater boxes (2), a serial communication port, one side fixed mounting that outer furnace body (1) was kept away from in heater box (2) has flexible pneumatic cylinder (4), the output fixed mounting of flexible pneumatic cylinder (4) has telescopic shaft (5), one side fixed mounting that telescopic shaft (5) are close to filter screen (3) has three cleaning brush (6), one side that telescopic shaft (5) were kept away from in three cleaning brush (6) all contacts with filter screen (3), spout (7) that are located filter screen (3) top are seted up to one side that heater box (2) are close to telescopic shaft (5), fixed mounting has same slide bar (8) on the top side of spout (7) and the bottom side inner wall.

2. The device for reducing the self-explosion rate of the homogenizing furnace according to claim 1, wherein a sliding column (9) is sleeved on the sliding rod (8) in a sliding mode, one end of the sliding column (9) extends out of the sliding groove (7), the top side and one side of the sliding column (9) are provided with the same L-shaped sliding hole (10), an L-shaped sliding rod (11) is installed in the L-shaped sliding hole (10) in a sliding mode, two ends of the L-shaped sliding rod (11) extend out of the L-shaped sliding hole (10), one side, far away from the telescopic shaft (5), of the L-shaped sliding rod (11) is rotatably provided with a pull rod (12), and the top end of the pull rod (12) is rotatably installed on one side of the heating box (2).

3. The auto-explosion rate reducing device for the homogenizing furnace according to claim 2, wherein a push rod (13) is rotatably mounted at the bottom side of the sliding column (9), a rotating rod (14) is rotatably mounted at the bottom end of the push rod (13), a support rod (15) is rotatably mounted at one side of the rotating rod (14), one end of the support rod (15) far away from the rotating rod (14) is fixedly mounted at one side of the heating box (2), an impact rod (16) is fixedly mounted at one side of the rotating rod (14) far away from the telescopic shaft (5), and the bottom end of the impact rod (16) is in contact with one side of the filter screen (3).

4. The device for reducing the spontaneous explosion rate of the homogenizing furnace according to claim 1, wherein a groove (17) is formed in one side, close to the heating box (2), of the telescopic shaft (5), a wedge-shaped rod (18) is slidably mounted in the groove (17), one end of the wedge-shaped rod (18) extends out of the groove (17) and corresponds to the position of the L-shaped sliding rod (11), one end, far away from the heating box (2), of the wedge-shaped rod (18) is fixedly mounted with one end of a first spring, and the other end of the first spring is fixedly mounted on the inner wall of one side of the groove (17).

5. The device for reducing the spontaneous explosion rate of the homogenizing furnace according to claim 1, wherein a second spring is sleeved on the sliding rod (8), the top end of the second spring is fixedly installed on the bottom side of the sliding column (9), and the bottom end of the second spring is fixedly installed on the inner wall of the bottom side of the sliding chute (7).

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