CN210832937U - Intelligent glass dryer - Google Patents

Abstract

The utility model relates to a desiccator technical field, concretely relates to intelligence glass drying machine, including the drying cabinet, drying cabinet import left end is equipped with the deflector roll, and deflector roll support frame left side end is equipped with first pressure sensor, and drying cabinet export right-hand member also is equipped with deflector roll and deflector roll support frame right side end and is equipped with second pressure sensor, and drying cabinet right flank bottom is connected with a drive case, and inside intake pipe department that is close to of drying cabinet is equipped with the aviation baffle, also is equipped with the deflector roll between drying cabinet import and the drying cabinet export, and drying cabinet medial surface bottom is equipped with humidity transducer. The utility model discloses can realize treating the full-automatic drying process of processing glass, and hot-blast flow distribution on glass upper and lower surface is even, can not cause glass crimping in drying process, and drying quality is good, and drying efficiency is high, has saved manpower and manufacturing cost.

Description

Intelligent glass dryer

Technical Field

The utility model relates to a desiccator technical field, concretely relates to intelligence glass desiccator.

Background

Drying is a core process link in the glass processing process, the traditional drying process usually adopts a heating pipe or natural gas, the heating mode is energy-consuming, the drying effect is poor, the product quality cannot be guaranteed, and the glass dryer specially used for glass drying can guarantee the drying effect and save energy consumption. The traditional heating mode is that air is heated firstly, then the air transmits a heat source to a heated object, the heated object is in a transmission mode of slowly permeating from the outside to the inside, the medium wave heating mode of the glass dryer is a heating mode of integrating the outside and the inside, and integrating the outside and the inside, so that friction heat generated by vibration of internal molecules or atoms of the heated object is generated, and the glass dryer is different from the traditional drying mode. At present glass is in the manufacturing process, inside can produce partial moisture, need dry the moisture in the glass, nevertheless because of glass self deformation temperature is low, so certainly can take place to curl under certain high temperature condition, adopt traditional air-dry mode to dry, the flow of wind is uneven surface distribution about glass, very easily causes the curl, drying quality is poor, influences glass's subsequent processing, drying efficiency is low, and the development of current glass desiccator in intelligent automation field is also very deficient.

SUMMERY OF THE UTILITY MODEL

For solving the problem that exists, the utility model provides an intelligence glass drying machine can realize treating the full-automatic drying process of processing glass, and hot-blast flow distribution on glass upper and lower surface is even, can not cause the curling deformation of glass in drying process, and drying quality is good, and drying efficiency is high, has saved manpower and manufacturing cost.

The utility model provides an intelligence glass drying machine, includes the drying cabinet, the drying cabinet top is connected with the intake pipe, the drying cabinet bottom is connected with the outlet duct, drying cabinet left surface middle part is equipped with the drying cabinet import, drying cabinet import left end is equipped with the deflector roll, deflector roll support frame left side end is equipped with first pressure sensor, drying cabinet right side middle part is equipped with the drying cabinet export, drying cabinet export right-hand member also is equipped with the deflector roll just deflector roll support frame right side end is equipped with second pressure sensor, drying cabinet right side bottom is connected with a drive case, the inside air-guide plate that is close to of drying cabinet intake pipe department, the drying cabinet import with also be equipped with between the drying cabinet export the deflector roll, drying cabinet medial surface bottom is equipped with humidity transducer.

Preferably, the inlet of the air inlet pipe is connected with a high-pressure hot air blower.

Preferably, an exhaust fan is connected to an outlet of the air outlet pipe.

Preferably, the outlet of the drying box is connected with a timing device.

Preferably, the air deflector is uniformly divided into grid-shaped air ports.

Preferably, the first pressure sensor, the second pressure sensor and the humidity sensor are all connected with the driving box through lines.

The utility model has the advantages that: the utility model discloses can realize treating the full-automatic drying process of processing glass, and hot-blast flow distribution on glass upper and lower surface is even, can not cause glass crimping in drying process, and drying quality is good, and drying efficiency is high, has saved manpower and manufacturing cost.

Drawings

Fig. 1 is the utility model relates to an intelligence glass drying machine schematic structure.

Fig. 2 is the utility model relates to an intelligence glass drying machine drying cabinet inner structure schematic diagram.

Fig. 3 is the utility model discloses an intelligence glass drying machine aviation baffle structure sketch map.

In fig. 1: 1-a guide roller; 2-a first pressure sensor; 3-drying oven; 4-inlet of drying box; 5-outlet of drying oven; 6, an air inlet pipe; 7-an air outlet pipe; 8-a wind deflector; 9-a humidity sensor; 10-a second pressure sensor; 11-drive box.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

As shown in fig. 1, 2 and 3, an intelligent glass dryer comprises a drying box 3, an air inlet pipe 6 is connected to the top of the drying box 3, the bottom of the drying box 3 is connected with an air outlet pipe 7, the middle part of the left side surface of the drying box 3 is provided with a drying box inlet 4, the left end of the drying box inlet 4 is provided with a guide roller 1, the tail end of the left side of the supporting frame of the guide roller 1 is provided with a first pressure sensor 2, a drying box outlet 5 is arranged in the middle of the right side surface of the drying box 3, the right end of the drying box outlet 5 is also provided with the guide roller 1, the tail end of the right side of the support frame of the guide roller 1 is provided with a second pressure sensor 10, the bottom of the right side surface of the drying box 3 is connected with a driving box 11, a wind deflector 8 is arranged in the drying box 3 and close to the air inlet pipe 6, drying cabinet import 4 with also be equipped with between drying cabinet export 5 deflector roll 1, 3 medial surface bottoms of drying cabinet are equipped with humidity transducer 9. The inlet of the air inlet pipe 6 is connected with a high-pressure air heater. An exhaust fan is connected at the outlet of the air outlet pipe 7. The outlet 5 of the drying box is connected with a timing device. The air deflector 8 is evenly divided into grid-shaped air ports. The first pressure sensor 2, the second pressure sensor 10 and the humidity sensor 9 are all connected with the driving box 11 through lines.

In the use process of the intelligent glass dryer, the top of the drying box 3 is connected with an air inlet pipe 6, and the inlet of the air inlet pipe 6 is connected with a high-pressure air heater. The bottom of the drying box 3 is connected with an air outlet pipe 7, and the outlet of the air outlet pipe 7 is connected with an exhaust fan. 3 left surface middle parts of drying cabinet are equipped with drying cabinet import 4, and 4 left ends of drying cabinet import are equipped with deflector roll 1, and 1 support frame left side end of deflector roll is equipped with first pressure sensor 2, and 3 right flank middle parts of drying cabinet are equipped with drying cabinet export 5, and drying cabinet export 5 is connected with a timing device. 5 right-hand members in drying cabinet export also are equipped with deflector roll 1 and deflector roll 1 support frame right side end is equipped with second pressure sensor 10, and 3 right flank bottoms in drying cabinet are connected with a drive case 11, and the inside intake pipe 6 departments that are close to of drying cabinet 3 are equipped with aviation baffle 8, and aviation baffle 8 evenly cuts apart into grid form wind gap. A guide roller 1 is also arranged between the drying box inlet 4 and the drying box outlet 5, and a humidity sensor 9 is arranged at the bottom of the inner side surface of the drying box 3. The first pressure sensor 2, the second pressure sensor 10 and the humidity sensor 9 are all connected with the driving box 11 through lines. When glass to be processed is arranged on a guide roller at the left end of a drying box 3, a first pressure sensor 2 transmits a signal to a driving box 11, the driving box 11 controls a guide roller 1 to rotate to transmit the glass, meanwhile, the driving box 11 controls an inlet 4 of the drying box to be opened, the glass to be processed enters the drying box 3 to be dried, when the glass is dried to set allowable humidity, a humidity sensor 9 transmits the signal to the driving box 11, the driving box 11 controls an outlet 5 of the drying box to be opened, the guide roller 1 in the drying box 3 sends the dried glass out, the opening time of the outlet 5 of the drying box is controlled by a timing device connected with the drying box, when the dried glass is arranged on the guide roller 1 at the right side of the drying box 3, a second pressure sensor transmits the signal to the driving box 11, the driving box controls the guide roller 1 at the right side of the drying box 3 to rotate. The device can realize the full-automatic drying process of glass to be processed, the flow distribution of hot air on the upper surface and the lower surface of the glass is uniform, the curling deformation of the glass in the drying process can not be caused, the drying quality is good, the drying efficiency is high, and the manpower and the production cost are saved.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modification, equivalent replacement or improvement made within the spirit and principle of the present invention should be included in the present invention.

Claims (6)

1. The utility model provides an intelligence glass drying machine which characterized in that: including the drying cabinet, the drying cabinet top is connected with the intake pipe, the drying cabinet bottom is connected with the outlet duct, drying cabinet left surface middle part is equipped with the drying cabinet import, drying cabinet import left end is equipped with the deflector roll, deflector roll support frame left side end is equipped with first pressure sensor, drying cabinet right flank middle part is equipped with the drying cabinet export, drying cabinet export right-hand member also is equipped with the deflector roll just deflector roll support frame right side end is equipped with second pressure sensor, drying cabinet right side face bottom is connected with a drive case, the inside being close to of drying cabinet intake pipe department is equipped with the aviation baffle, the drying cabinet import with also be equipped with between the drying cabinet export the deflector roll, drying cabinet medial surface bottom is equipped with humidity transducer.

2. The intelligent glass dryer of claim 1, wherein: and the inlet of the air inlet pipe is connected with a high-pressure air heater.

3. The intelligent glass dryer of claim 1, wherein: and an exhaust fan is connected at the outlet of the air outlet pipe.

4. The intelligent glass dryer of claim 1, wherein: the outlet of the drying box is connected with a timing device.

5. The intelligent glass dryer of claim 1, wherein: the air deflector is evenly divided into grid-shaped air ports.

6. The intelligent glass dryer of claim 1, wherein: the first pressure sensor, the second pressure sensor and the humidity sensor are all connected with the driving box through lines.

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