CN213388356U

CN213388356U - Glass homogenizing furnace

Info

Publication number: CN213388356U
Application number: CN202020991354.8U
Authority: CN
Inventors: 李昊鹏; 纵峰; 殴阳马龙
Original assignee: Anhui Gold Coronet Glass Co ltd
Current assignee: Anhui Gold Coronet Glass Co ltd
Priority date: 2020-06-03
Filing date: 2020-06-03
Publication date: 2021-06-08
Anticipated expiration: 2030-06-03

Abstract

The utility model belongs to the field of glass processing, in particular to a glass homogenizing furnace, which comprises a device main body, a furnace body and a heating pipe, wherein the bottom of the device main body is fixedly connected with the furnace body, the inner wall of the furnace body is embedded and connected with a base, the top of the base is movably connected with a rotating shaft, the top of the rotating shaft is movably connected with the heating pipe, the middle of the heating pipe is movably connected with a movable shaft, the top of the heating pipe is movably connected with a slide way, the bottom of the furnace body is embedded and connected with a slide block, the inside of the slide block is connected with a groove in a penetrating way, the arrangement of the groove can lead a movable mechanism to move in the groove, a worker can disassemble a positioning rod, then when needing to process single glass, the redundant positioning rod is taken out, the heat in the device main body is not used by, so that the residual nickel sulfide in the glass can be eliminated, and the movable mechanism has wide development prospect in the future.

Description

Glass homogenizing furnace

Technical Field

The utility model relates to the field of glass processing, in particular to a glass homogenizing furnace.

Background

Present homogeneity stove, can't carry out the omnidirectional to glass and heat, let glass be heated inhomogeneously, thereby lead to glass to arouse the spontaneous explosion after homogeneity stove processing, make homogeneity stove processing failure back, the glass piece flies all day, and current homogeneity stove can't dismantle the shelf of placing glass, lead to the staff when single glass of needs processing, need all remove inside the homogeneity stove whole shelf, make the homogeneity stove still must heat the shelf, and then waste the heat in the place that need not heat.

Therefore, how to design a glass homogenizing furnace becomes a problem which needs to be solved currently.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass homogeneity stove to propose in solving above-mentioned background art can't carry out the omnidirectional to glass and heat, can't carry out the problem of dismantling with the shelf of placing glass.

In order to achieve the above object, the utility model provides a following technical scheme: a glass homogenizing furnace comprises a device main body, a furnace body and a heating pipe, wherein the bottom of the device main body is fixedly connected with the furnace body, the inner wall of the furnace body is embedded and connected with a base, the top of the base is movably connected with a rotating shaft, the top of the rotating shaft is movably connected with the heating pipe, the middle of the heating pipe is movably connected with a movable shaft, the top of the heating pipe is movably connected with a slide way, the bottom of the furnace body is embedded and connected with a slide block, the inside of the slide block is connected with a groove in a penetrating manner, the top of the groove is movably connected with a pulley, the top of the pulley is movably connected with a supporting rod, the other side of the supporting rod is movably connected with a bayonet lock, one side of the bayonet lock is connected with a clamping groove in a, one side of the furnace body is movably connected with a heat dissipation valve.

Preferably, the top of the device main part is embedded and connected with an air cooler, and the top of the air cooler is fixedly connected with a heat radiator.

Preferably, the other side of the device main body is movably connected with a double door, and the top of the double door is fixedly connected with a bayonet.

Preferably, the bottom of the sliding block is movably connected with a scrap box.

Preferably, the heating device is formed by combining a base of the inner wall of the furnace body, a rotating shaft at the top of the base, a heating pipe at the top of the rotating shaft, a movable shaft in the middle of the heating pipe and a slideway at the top of the heating pipe.

Preferably, the movable mechanism is formed by combining a sliding block at the bottom of the furnace body, a groove in the sliding block, a pulley at the top of the groove, a supporting rod at the top of the pulley, a clamping pin at the other side of the supporting rod, a clamping groove at one side of the clamping pin, a ring on the periphery of the clamping groove, a positioning rod at the top of the ring and a positioning block at the top of the supporting rod.

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

1. this kind of glass homogeneity stove through heating device's setting, can the omnidirectional heat glass for glass atress is even, and then eliminates remaining nickel sulfide in the glass, lets the device main part can process glass effectively.

2. This kind of glass homogeneity stove through the setting of movable mechanism, can take out unnecessary locating lever, only leaves a locating lever, prevents that unnecessary locating lever from still must letting the device main part heat the locating lever after putting into the device main part, and then increases the heat energy that the device main part consumed, and takes out unnecessary locating lever, can reduce the heat energy that the device main part consumed effectively, and the staff of being convenient for again dismantles the locating lever.

Drawings

FIG. 1 is a schematic diagram of the structure of the main body of the device of the present invention;

fig. 2 is a schematic front sectional view of the device main body of the present invention;

fig. 3 is a schematic top sectional view of the device main body according to the present invention;

fig. 4 is a schematic, diagrammatic side plan view of a shelf of the present invention;

fig. 5 is a schematic diagram of the structure of the device a of the present invention.

In the figure: 1. the device comprises a device main body, 2, a heat radiator, 3, an air cooler, 4, a furnace body, 5, double doors, 6, bayonets, 7, grooves, 8, positioning rods, 9, sliding blocks, 10, supporting rods, 11, a heat radiating valve, 12, a slide way, 13, a base, 14, a rotating shaft, 15, a heating pipe, 16, a movable shaft, 17, a circular ring, 18, a clamping groove, 19, a clamping pin, 20, a positioning block, 21, a pulley, 22 and a scrap box.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by a person of ordinary skill in the art without creative work belong to the protection scope of the present invention based on the embodiments of the present invention.

In a first embodiment, please refer to fig. 1-5, the present invention provides a technical solution: a glass homogenizing furnace comprises a device main body 1, a furnace body 4 and a heating pipe 15, the bottom of the device main body 1 is fixedly connected with the furnace body 4, the inner wall of the furnace body 4 is embedded and connected with a base 13, the top of the base 13 is movably connected with a rotating shaft 14, the top of the rotating shaft 14 is movably connected with the heating pipe 15, the middle of the heating pipe 15 is movably connected with a movable shaft 16, the top of the heating pipe 15 is movably connected with a slide 12, the bottom of the furnace body 4 is embedded and connected with a slide block 9, the inside of the slide block 9 is connected with a groove 7 in a penetrating way, the top of the groove 7 is movably connected with a pulley 21, the top of the pulley 21 is movably connected with a supporting rod 10, the other side of the supporting rod 10 is movably connected with a bayonet lock 19, one side of the bayonet lock 19 is connected, one side of the furnace body 4 is movably connected with a heat dissipation valve 11.

Preferably, an air cooler 3 is embedded and connected in the top of the device main body 1, a radiator 2 is fixedly connected to the top of the air cooler 3, after the device main body 1 removes nickel sulfide in glass, a worker can open the air cooler 3 in the top of the device main body 1, high temperature in the device main body 1 is slowly reduced through the refrigeration and powerful air blowing effects of the air cooler 3, then the high temperature is blown towards the radiator 2 in the top of the air cooler 3, so that the high temperature in the device main body 1 is discharged from the radiator 2, after the temperature in the device main body 1 is reduced, the worker can take out the processed glass, the high temperature in the device main body 1 is prevented from not being eliminated, the worker takes out the glass from the device main body 1, the glass is fused with external media in a high temperature state, and the glass processing fails, the temperature inside the device body 1 and the glass are reduced in advance, and the processing efficiency of the device body 1 can be effectively improved.

Preferably, the opposite side swing joint of device main part 1 has two door 5, two 5 top fixedly connected with bayonets 6 of opening door, when the staff uses device main part 1 to process glass, the staff need use the two 5 of opening door of 1 opposite side of device main part to seal device main part 1, make the high temperature in the device main part 1 can outwards not spill over, then block the fixed block with bayonet 6 contact through the bayonet 6 at two 5 tops of opening door, because the fixed block is integrative with two door 5 of opening door, so block behind the fixed block at bayonet 6, just can be in the same place two 5 fixed with furnace body 4 of opening door, and then seal device main part 1, guarantee to normally process glass in the device main part 1, the leakproofness of device main part 1 has been improved effectively.

Preferably, the bottom of the sliding block 9 is movably connected with a scrap box 22, when the device main body 1 is used for processing glass, if the heating in the device main body 1 is not stable enough, the glass can explode in the device main body 1, so that the glass fragments after explosion can fill the whole furnace body 4, and fall to the bottom of the furnace body 4 under the action of gravity, so that the working personnel can not clean the glass fragments in the device main body 1 well, the scrap box 22 is arranged at the bottom of the sliding block 9, after glass explodes automatically, the fragments can fall downwards under the effect of gravity, the scrap box 22 is just arranged under the furnace body 4, so that the glass scraps can be collected into the scrap box 22, and then after the device main body 1 runs a flow, the working personnel can take out the scrap box 22 from the bottom of one side of the device main body 1, and further process the scraps contained in the scrap box 22, the sanitary environment in the apparatus main body 1 is effectively secured.

Preferably, the heating device is formed by combining a base 13 on the inner wall of the furnace body 4, a rotating shaft 14 at the top of the base 13, a heating pipe 15 at the top of the rotating shaft 14, a movable shaft 16 in the middle of the heating pipe 15 and a slideway 12 at the top of the heating pipe 15, after a worker pushes a moving mechanism with glass to the device main body 1, the base 13 is arranged on the inner wall of the furnace body 4 between each two pieces of glass, the rotating shaft 14 is arranged at the top of the base 13, the heating pipe 15 at the top of the rotating shaft 14 can be driven to move after the worker controls the rotating shaft 14 to move on the base 13, the movable shaft 16 in the middle of the heating pipe 15 can be driven by the rotating shaft 14 along with the heating pipe 15, the heating pipe 15 is moved on a sliding knife 12 at the top of the heating pipe 15 in a telescopic manner, and then after a control switch outside the, then heat the glass of heating pipe 15 both sides, and heating pipe 15 can be followed glass's one side to glass's opposite side, reach the omnidirectional and heat glass, prevent that heating pipe 15 from heating glass man-hour, can't carrying out the omnidirectional to glass and heating, it is inhomogeneous to let glass be heated, lead to glass spontaneous explosion in device main part 1, make device main part 1 processing failure, and heating device's setting can the omnidirectional heat glass, make the glass atress even, and then eliminate remaining nickel sulfide in the glass, let device main part 1 can process glass effectively.

Preferably, the movable mechanism is formed by combining a sliding block 9 at the bottom of the furnace body 4, a groove 7 in the sliding block 9, a pulley 21 at the top of the groove 7, a supporting rod 10 at the top of the pulley 21, a clamping pin 19 at the other side of the supporting rod 10, a clamping groove 18 at one side of the clamping pin 19, a ring 17 at the periphery of the clamping groove 18, a positioning rod 8 at the top of the ring 17 and a positioning block 20 at the top of the supporting rod 10 together, when a worker needs to take out the supporting rod, the worker can move the supporting rod 10 from the device body 1 along the sliding block 9 at the bottom of the furnace body 4 or move the supporting rod 10 from the outside of the device body 1 to the inside of the device body 1 because the pulley 21 is arranged at the bottom of the supporting rod 10 and the groove 7 is arranged in the sliding block 9, and then the worker can use the clamping pin, when the ring 17 at the periphery of the clamping groove 18 is matched with the clamping groove 18, the clamping pin 19 is inserted into the clamping groove 18 at one side of the clamping pin 19, because the ring 17 and the positioning rod 8 at the top of the ring 17 are integrated, the positioning rod 8 can be fixed in the clamping groove 18, then when a worker places glass on the supporting rod 10, the bottom of the glass is fixed by the positioning block 20 at the top of the supporting rod 10, the top of the glass leans against the positioning rod 8, the worker can move the movable mechanism into the device main body 1, and when the worker carries out single glass processing, the clamping pin 19 can be pulled out from the clamping groove 18, then the redundant positioning rod 8 is taken out, only one positioning rod 8 is left, the redundant positioning rod 8 is prevented from being placed into the device main body 1, the device main body 1 is still required to heat the positioning rod 8, and the heat energy consumed by the device main body 1 is increased, and take out unnecessary locating lever 8, can reduce the heat energy that device main part 1 consumed effectively, can also be convenient for the staff to dismantle locating lever 8.

The working principle is as follows: firstly, after the device main body 1 removes the nickel sulfide in the glass, a worker can open the air cooler 3 in the top of the device main body 1, the high temperature in the device main body 1 is slowly reduced through the refrigeration and powerful air blowing effects of the air cooler 3, then the high temperature is blown to the direction of the heat radiator 2 at the top of the air cooler 3, so that the high temperature in the device main body 1 is discharged from the heat radiator 2, after the temperature inside the device main body 1 is reduced, the working personnel can take out the processed glass, so that the situation that the high temperature inside the device main body 1 is not eliminated is avoided, the working personnel takes out the glass from the device main body 1, the glass is fused with an external medium in a high-temperature state, and the glass processing fails, the temperature inside the device body 1 and the glass are reduced in advance, and the processing efficiency of the device body 1 can be effectively improved.

Then, when the staff used device main part 1 to process glass, the staff needed to use the two door 5 of 1 opposite sides of device main part to seal device main part 1, make the high temperature in the device main part 1 can not outwards spill over, then block the fixed block with 6 contacts of bayonet socket through the bayonet socket 6 at 5 tops of two door, because the fixed block is integrative with two door 5, so block behind the fixed block at bayonet socket 6, just can be in the same place two door 5 and furnace body 4 are fixed, and then seal device main part 1, guarantee to normally process glass in the device main part 1, the leakproofness of device main part 1 has been improved effectively.

Then, when the glass is processed by the apparatus body 1, if the temperature in the apparatus body 1 is not stable enough, the glass may explode in the apparatus body 1, and the glass fragments after explosion may be filled in the entire furnace body 4, because of gravity, the glass scraps fall to the bottom of the furnace body 4, so that the workers cannot clean the glass scraps in the device main body 1 easily, the bottom of the sliding block 9 is provided with a scrap box 22, after the glass is subjected to spontaneous explosion, the scraps can fall downwards due to the gravity effect of the earth center, and the scrap box 22 is arranged right below the furnace body 4, so that the glass scraps can be collected into the scrap box 22, then, after the apparatus body 1 has run through one process, the worker takes out the scrap box 22 from the bottom of one side of the apparatus body 1, further, the waste contained in the waste box 22 is disposed of, and the sanitary environment in the apparatus main body 1 is effectively ensured.

Next, after the worker puts the moving mechanism propulsion device body 1 with the glass, a base 13 is arranged on the inner wall of the furnace body 4 between each glass, a rotating shaft 14 is arranged on the top of the base 13, after the worker controls the rotating shaft 14 to move on the base 13, a heating pipe 15 on the top of the rotating shaft 14 can be driven to move, a movable shaft 16 in the middle of the heating pipe 15 can be driven by the rotating shaft 14 along with the heating pipe 15 to make the heating pipe 15 do telescopic motion on a sliding knife 12 on the top of the heating pipe 15, then after a control switch outside the control device body 1 of the worker, two corresponding heating pipes 15 are extended, then the glass on two sides of the heating pipe 15 is heated, and the heating pipe 15 can go from one side of the glass to the other side of the glass, so as to achieve omnibearing heating of the glass, and prevent the heating pipe 15 from heating the glass during processing, unable carry out the omnidirectional to glass and heat, let glass be heated inhomogeneously, lead to glass spontaneous explosion in device main part 1 for device main part 1 processing fails, and heating device's setting can the omnidirectional heat glass, makes glass atress even, and then eliminates remaining nickel sulfide in the glass, lets device main part 1 can process glass effectively.

Finally, when the worker needs to take out the glass, the worker can move the supporting rod 10 on the top of the pulley 21, because the pulley 21 is arranged at the bottom of the supporting rod 10, the pulley 21 is arranged at the top of the groove 7, the groove 7 is arranged inside the slider 9, the supporting rod 10 can be moved out of the device body 1 along the slider 9 at the bottom of the furnace body 4, or moved into the device body 1 from the outside of the device body 1, then the worker can use the bayonet 19 at the other side of the supporting rod 10, when the ring 17 at the periphery of the bayonet 18 is matched with the bayonet 18, the bayonet 19 is inserted into the bayonet 18 at one side of the bayonet 19, because the ring 17 and the positioning rod 8 at the top of the ring 17 are integrated, the positioning rod 8 can be fixed in the bayonet 18, and then when the worker places the glass on the supporting rod 10, the bottom of the glass is fixed by the positioning block 20, and glass's top leans on locating lever 8, the staff just can move the moving mechanism into inside device main part 1, and carry out solitary glass processing when the staff, can be through extracting bayonet lock 19 from draw-in groove 18, then take out unnecessary locating lever 8, only leave a locating lever 8, prevent unnecessary locating lever 8 after putting into device main part 1, still must let device main part 1 heat locating lever 8, and then increase the heat energy that device main part 1 consumed, and take out unnecessary locating lever 8, can reduce the heat energy that device main part 1 consumed effectively, the staff of also being convenient for dismantles locating lever 8.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a glass homogeneity stove, includes device main part (1), furnace body (4) and heating pipe (15), its characterized in that: the device comprises a device body (1), a furnace body (4) is fixedly connected to the bottom of the device body (1), a base (13) is connected to the inner wall of the furnace body (4) in an embedded mode, a rotating shaft (14) is movably connected to the top of the base (13), a heating pipe (15) is movably connected to the top of the rotating shaft (14), a movable shaft (16) is movably connected to the middle of the heating pipe (15), a slide way (12) is movably connected to the top of the heating pipe (15), a sliding block (9) is connected to the bottom of the furnace body (4) in an embedded mode, a groove (7) is connected to the inside of the sliding block (9) in a penetrating mode, a pulley (21) is movably connected to the top of the groove (7), a supporting rod (10) is movably connected to the top of the pulley (21), a clamping pin, the periphery of the clamping groove (18) is movably connected with a circular ring (17), the top of the circular ring (17) is fixedly connected with a positioning rod (8), and the top of the supporting rod (10) is fixedly connected with a positioning block (20).

2. A glass homogenizing furnace according to claim 1, characterized in that: one side of the furnace body (4) is movably connected with a heat dissipation valve (11).

3. A glass homogenizing furnace according to claim 1, characterized in that: the device is characterized in that an air cooler (3) is embedded into the top of the device main body (1), and a heat radiator (2) is fixedly connected to the top of the air cooler (3).

4. A glass homogenizing furnace according to claim 1, characterized in that: the device is characterized in that the other side of the device body (1) is movably connected with a double door (5), and the top of the double door (5) is fixedly connected with a bayonet (6).

5. A glass homogenizing furnace according to claim 1, characterized in that: the bottom of the sliding block (9) is movably connected with a scrap box (22).

6. A glass homogenizing furnace according to claim 1, characterized in that: the heating device is formed by combining a base (13) on the inner wall of the furnace body (4), a rotating shaft (14) at the top of the base (13), a heating pipe (15) at the top of the rotating shaft (14), a movable shaft (16) in the middle of the heating pipe (15) and a slide way (12) at the top of the heating pipe (15).

7. A glass homogenizing furnace according to claim 1, characterized in that: the furnace body is characterized in that a sliding block (9) at the bottom of the furnace body (4), a groove (7) in the sliding block (9), a pulley (21) at the top of the groove (7), a supporting rod (10) at the top of the pulley (21), a clamping pin (19) at the other side of the supporting rod (10), a clamping groove (18) at one side of the clamping pin (19), a circular ring (17) at the periphery of the clamping groove (18), a positioning rod (8) at the top of the circular ring (17) and a positioning block (20) at the top of the supporting rod (10) are jointly combined to form a.