阅读说明：本技术 一种多功能纳米硅玻璃均质炉 (Multifunctional nano-silica glass homogenizing furnace ) 是由 李忠林 于 2021-08-19 设计创作，主要内容包括：本发明公开一种多功能纳米硅玻璃均质炉,涉及均质炉领域。该一种多功能纳米硅玻璃均质炉,所述炉体的一侧安装有扶梯,且炉体的两侧均连接有多个内饰门,所述内饰门的内部开设有出风口,且内饰门的一侧安装有限位块,所述限位块的上表面和下表面均开设有两个限位孔,所述滑动机构包括两个固定板,两个所述固定板安装在限位块一侧,且滑动机构通过固定块和限位块安装在内饰门的一侧。该一种多功能纳米硅玻璃均质炉,可以加工横向放置的玻璃,从而提高工作效率,增加均质炉的功能,且设置的出风口,可以打开和关闭。(The invention discloses a multifunctional nano-silica glass homogenizing furnace, and relates to the field of homogenizing furnaces. This multi-functional nanometer silicate glass homogeneity stove, the staircase is installed to one side of furnace body, and the both sides of furnace body all are connected with a plurality of interior door, the air outlet has been seted up to the inside of interior door, and one side of interior door installs the stopper, two spacing holes have all been seted up to the upper surface and the lower surface of stopper, slide mechanism includes two fixed plates, two the fixed plate is installed in stopper one side, and slide mechanism passes through fixed block and stopper and installs the one side at the interior door. This multi-functional nanometer silicate glass homogeneity stove can process the glass of transversely placing to improve work efficiency, increase the function of homogeneity stove, and the air outlet that sets up can be opened and closed.)

1. A multifunctional nano-silica glass homogenizing furnace is characterized by comprising:

the heating furnace comprises a furnace body (1), wherein an escalator (101) is installed on one side of the furnace body (1), the inner side wall of the furnace body (1) is connected with a plurality of interior door (2), a heating wire (207) is arranged between the interior door (2) and the furnace body (1), an air outlet (201) is formed in the interior door (2), a limiting block (202) is installed on one side of the interior door (2), and two limiting holes (203) are formed in the upper surface and the lower surface of the limiting block (202);

the sliding mechanism comprises two fixing plates (204), the two fixing plates (204) are installed on one side of the limiting block (202), and the sliding mechanism is installed on one side of the interior trim door (2) through the fixing blocks and the limiting block (202).

2. The multifunctional nano-silica glass homogenizing furnace according to claim 1, characterized in that: the sliding mechanism further comprises a moving block (205), the moving block (205) is connected to the inside of the limiting block (202), one side of the moving block (205) is attached to the inner wall of the fixing plate (204), through grooves (206) are formed in the upper surface and the lower surface of the moving block (205), and hollow grooves (3) are formed in the moving block (205).

3. The multifunctional nano-silica glass homogenizing furnace according to claim 2, characterized in that: slide mechanism still includes gear (301), gear (301) are connected on the inside wall of dead slot (3), and gear (301) keep away from the one end of the inside wall of dead slot (3) and install dwang (302), the surface of movable block (205) is run through to the one end of dwang (302), and handle (303) are installed to the one end of dwang (302).

4. The multifunctional nano-silica glass homogenizing furnace according to claim 3, characterized in that: two sides of the gear (301) are respectively meshed with a first rack (304) and a second rack (305), and one ends of the first rack (304) and the second rack (305) respectively penetrate through the two through grooves (206) and are inserted into one limiting hole (203).

5. The multifunctional nano-silica glass homogenizing furnace according to claim 4, characterized in that: elastic pieces (306) are mounted on the lower surface of the first rack (304) and the upper surface of the second rack (305), and one end, far away from the first rack (304) and the second rack (305), of each elastic piece (306) is mounted on the inner side wall of the empty groove (3).

6. The multifunctional nano-silica glass homogenizing furnace according to claim 5, characterized in that: two baffles (307) are installed on the inner side wall of the empty groove (3), and the two baffles (307) are respectively attached to one sides of the first rack (304) and the second rack (305).

Technical Field

The invention relates to the technical field of homogenizing furnaces, in particular to a multifunctional nano-silica glass homogenizing furnace.

Background

The toughened glass homogenizing furnace is detection equipment for toughened glass finished products, the toughened glass is fed into the homogenizing furnace after the glass toughening procedure is finished, detonation test and residual nickel sulfide elimination are carried out according to the hot dipping principle of the homogenizing furnace, and toughened glass with the potential self-explosion hazard, namely the toughened glass with uneven glass internal stress is detonated in advance in the test process, so that the safety and reliability of the toughened glass of the building are improved;

most homogeneity stove can only be placed glass is vertical when using at present, but glass does need transversely to place a bit, consequently makes most homogeneity stove's function singleness, and work efficiency is low, and the radiating effect is poor, and is not convenient for overhaul the heater, therefore we have provided a multi-functional nanometer silicate glass homogeneity stove.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention discloses a multifunctional nano-silica glass homogenizing furnace, which aims to solve the problems in the background technology.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: a multifunctional nano-silica glass homogenizing furnace comprises:

the heating furnace comprises a furnace body, wherein a staircase is installed on one side of the furnace body, the inner side wall of the furnace body is connected with a plurality of interior doors, heating wires are arranged between the interior doors and the furnace body, air outlets are formed in the interior doors, a limiting block is installed on one side of each interior door, and two limiting holes are formed in the upper surface and the lower surface of each limiting block;

and the sliding mechanism comprises two fixing plates, the two fixing plates are arranged on one side of the limiting block, and the sliding mechanism is arranged on one side of the interior trim door through the fixing block and the limiting block.

Preferably, the sliding mechanism further comprises a moving block, the moving block is connected inside the limiting block, one side of the moving block is attached to the inner wall of the fixed plate, through grooves are formed in the upper surface and the lower surface of the moving block, and empty grooves are formed in the moving block.

Preferably, slide mechanism still includes the gear, gear connection is on the inside wall of dead slot, and the gear is kept away from the one end of the inside wall of dead slot and is installed the dwang, the surface of movable block is run through to the one end of dwang, and the handle is installed to the one end of dwang.

Preferably, the two sides of the gear are respectively engaged with a first rack and a second rack, and one ends of the first rack and the second rack respectively penetrate through the two through grooves and are inserted into one of the limiting holes.

Preferably, the lower surface of the first rack and the upper surface of the second rack are both provided with an elastic part, and one end of the elastic part, which is far away from the first rack and the second rack, is provided with an inner side wall of the empty groove.

Preferably, two baffles are installed on the inner side wall of the empty groove, and the two baffles are respectively attached to one side of the first rack and one side of the second rack.

The invention discloses a multifunctional nano-silica glass homogenizing furnace, which has the following beneficial effects:

1. this multi-functional nanometer silica glass homogeneity stove can be opened the gas outlet through removing the movable block, and rotates the handle and can drive gear revolve to make first rack and second rack move to inside, peg graft and break away from the inside in spacing hole, thereby can fix the position of movable block, can open the air outlet and close the air outlet, consequently make glass can erect and put, also can violently put, thereby improve work efficiency, and the radiating block, the easy access heater.

2. This multi-functional nanometer silicate glass homogeneity stove drives gear revolve through rotating the handle, and gear revolve drives first rack and second rack and removes to compress the elastic component, thereby make first rack and second rack and spacing hole break away from, consequently can remove the movable block, and elasticity can also bounce-back, can make in the quick stopper that inserts of first rack and second rack.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the interior door structure of the present invention;

FIG. 3 is a schematic view of the internal mechanism of the limiting block according to the present invention;

fig. 4 is a schematic view of the internal structure of the moving block of the present invention.

In the figure: 1. a furnace body; 101. an escalator; 2. an interior door; 201. an air outlet; 202. a limiting block; 203. a limiting hole; 204. a fixing plate; 205. a moving block; 206. a through groove; 207. a heater; 3. an empty groove; 301. a gear; 302. rotating the rod; 303. a handle; 304. a first rack; 305. a second rack; 306. an elastic member; 307. and a baffle plate.

Detailed Description

The embodiment of the invention discloses a multifunctional nano-silica glass homogenizing furnace,

according to the attached drawing 1, one side of a furnace body 1 is fixedly connected with an escalator 101, the inner side wall of the furnace body 1 is rotatably connected with a plurality of interior doors 2, a heating wire 207 is arranged between each interior door 2 and the furnace body 1, an air outlet 201 is formed in each interior door 2, one side of each interior door 2 is fixedly connected with a limiting block 202, and the upper surface and the lower surface of each limiting block 202 are respectively provided with two limiting holes 203, so that the position of a moving block 205 can be conveniently fixed;

the sliding mechanism comprises two fixing plates 204, the two fixing plates 204 are fixedly connected to one side of the limiting block 202, the two fixing plates 204 can prevent the moving block 205 from falling off accidentally, and the sliding mechanism is installed on one side of the interior trim door 2 through the fixing block and the limiting block 202;

the air outlet 201 can be opened by moving the moving block 205, and the rotating handle 303 can drive the gear 301 to rotate, so that the first rack 304 and the second rack 305 move inwards, are inserted and separated from the inside of the limiting hole 203, the position of the moving block 205 can be fixed, the air outlet 201 can be opened and the air outlet 201 can be closed, and glass can be placed vertically or transversely.

As shown in fig. 3 and 4, the sliding mechanism further includes a moving block 205, the moving block 205 is slidably connected inside the limiting block 202, one side of the moving block 205 is attached to the inner wall of the fixed plate 204, through grooves 206 are formed in the upper surface and the lower surface of the moving block 205, and a hollow groove 3 is formed inside the moving block 205;

the sliding mechanism further comprises a gear 301 for driving a first rack 304 and a second rack 305 to move, the gear 301 is rotatably connected to the inner side wall of the empty slot 3, a rotating rod 302 is fixedly connected to one end, away from the inner side wall of the empty slot 3, of the gear 301, one end of the rotating rod 302 penetrates through the outer surface of the moving block 205, and a handle 303 is fixedly connected to one end of the rotating rod 302 and used for driving the gear 301 to rotate by rotating the handle 303;

a first rack 304 and a second rack 305 are respectively meshed with two sides of the gear 301, the first rack 304 and the second rack 305 are used for being inserted into the position of the limiting hole 203, so that the position of the moving block 205 is fixed, accidental closing is prevented, one ends of the first rack 304 and the second rack 305 respectively penetrate through the two through grooves 206 and are inserted into one limiting hole 203, the lower surface of the first rack 304 and the upper surface of the second rack 305 are both fixedly connected with an elastic part 306, the elastic part 306 can enable the first rack 304 and the second rack 305 to reset by utilizing the elastic effect, and one end, far away from the first rack 304 and the second rack 305, of the elastic part 306 is fixedly connected with the inner side wall of the empty groove 3;

two baffles 307 are fixedly connected to the inner side wall of the empty groove 3, and the two baffles 307 are respectively attached to one side of the first rack 304 and one side of the second rack 305;

the gear 301 is driven to rotate by rotating the handle 303, the gear 301 rotates to drive the first rack 304 and the second rack 305 to move, and the elastic part 306 is compressed, so that the first rack 304 and the second rack 305 are separated from the limiting hole 203, the moving block 205 can be moved, the elasticity can be rebounded, and the first rack 304 and the second rack 305 can be rapidly inserted into the limiting block 202.

The working principle is as follows: when the multifunctional nano-silica glass homogenizing furnace is used, firstly, when the furnace body 1 is used for detecting glass in working quality, the air outlet 201 of the interior door 2 needs to be opened, so that the glass can be conveniently and transversely placed for detection;

firstly, the handle 303 is grasped, then the handle 303 is rotated, the handle 303 is rotated to drive the rotating rod 302 to rotate, the rotating rod 302 is rotated to drive the gear 301 to rotate, the gear 301 rotates to enable the first rack 304 and the second rack 305 to move, the elastic part 306 is compressed when the first rack 304 and the second rack 305 move towards the inside of the hollow groove 3, and the first rack 304 and the second rack 305 cannot accidentally rotate and only can move up and down due to the fact that the two baffles 307 are attached to one sides of the first rack 304 and the second rack 305, and the first rack 304 and the second rack 305 are separated from the limiting hole 203;

then the handle 303 is moved to drive the moving block 205 to move along the inner wall of the limiting block 202, when the moving block moves to the top end of the limiting block 202, the handle 303 is loosened, the elastic part 306 loses the extrusion force and begins to rebound, so that the first rack 304 and the second rack 305 are driven to move and inserted into the other limiting hole 203, and the gear 301 drives the handle 303 to rotate, so that the air outlet 201 is opened, the heating wire 207 inside is exposed, the maintenance and the heat dissipation are facilitated, the glass which is transversely placed can be processed, and the working efficiency is improved;

the air outlet can be opened by moving the moving block 205, and the rotating handle 303 can drive the gear 301 to rotate, so that the first rack 304 and the second rack 305 move inwards, and the air outlet 201 can be opened and closed by inserting and separating from the inside of the limiting hole 203, thereby fixing the position of the moving block 205, so that the glass can be placed vertically or horizontally, thereby improving the working efficiency, increasing the function of the homogenizing furnace, the gear 301 is driven to rotate by rotating the rotating handle 303, the gear 301 rotates to drive the first rack 304 and the second rack 305 to move, and the elastic part 306 is compressed, thereby separating the first rack 304 and the second rack 305 from the limiting hole 203, thereby moving the moving block 205, and the elasticity can rebound, so that the first rack 304 and the second rack 305 can be quickly inserted into the limiting block 202.

The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.