CN209613480U - Screening plant for glass putty production - Google Patents

Abstract

The utility model relates to glass putty production fields, specifically disclose a kind of screening plant for glass putty production, including rack, feeding cylinder, screening bucket and gear cylinder are equipped in the rack along the vertical direction, the feeding cylinder is located above screening bucket and is connected to screening bucket, and feeding cylinder is fixedly connected with rack, the feeding cylinder sidewall is fixed with heating member；The screening bucket is connect with gantry rotation, bucket is sieved to be rotatablely connected with feeding cylinder simultaneously, the rack is equipped with the actuator that can drive screening bucket rotation, and being rotatably connected in the feeding cylinder can be affixed with the helical blade of screening bucket rotation, the helical blade outer rim with feeding cylinder inner wall；The screening barrel side wall is equipped with several sieve pores, and the gear cylinder is located at screening bucket periphery.Screening plant in the technical solution of this patent makes glass putty dry while sieving glass putty.

Description

Screening plant for glass putty production

Technical field

The utility model relates to glass putty production fields, and in particular to a kind of glass putty screening plant.

Background technique

Glass putty is widely used in galvanized iron plate processed, Ba Bituo alloy, glass putty foil, type metal, alloy, chemicals, manufacture electrical carbon The fields such as product, friction material, oiliness bearing, powder metallurgy.There are many manufacturing methods for glass putty, and wherein water fog method is excellent by its Formability, lower cost and higher nebulization efficiency and relative moderate price advantage become manufacture glass putty one kind it is main Method.Water fog method needs to be impacted with molten metal of the water of high flow rate to molten when manufacturing glass putty, keeps molten metal pulverized It is powder particles after these Drop Condensations, last powder particles are fallen into powder collector in drop that is of different sizes, coming in every shape.

The partial size of powder particles directly affects the performance of glass putty, needs to sieve glass putty after glass putty molding, according to tin The size of powder particles is classified glass putty.Using water fog method manufacture glass putty in be mixed into water, due to powder particles partial size compared with Small, wet powder particles are easy conglomeration, can not be sieved.Major part in the glass putty that will be moistened using high pressure general at present Water is extruded from powder collector, then spontaneously dries dewatered glass putty, but the time for spontaneously drying needs is longer, glass putty Drying efficiency is low, and the screening efficiency for finally resulting in glass putty is low.

Utility model content

The screening plant that the purpose of this utility model is to provide a kind of to make glass putty dry while sieving glass putty, to mention The screening efficiency of high glass putty.

The screening plant that achieve the above purpose, the technical solution of the present invention is: for glass putty production, including machine Frame, is equipped with feeding cylinder, screening bucket and gear cylinder in the rack along the vertical direction, the feeding cylinder be located above screening bucket and with sieve Divide bucket connection, and feeding cylinder is fixed with rack, the feeding cylinder sidewall is fixed with heating member；The screening bucket and gantry rotation connect It connects, screening bucket is rotatablely connected with feeding cylinder simultaneously, and the rack is equipped with the actuator that can drive screening bucket rotation, the charging Being rotatably connected in cylinder can be affixed with the helical blade of screening bucket rotation, the helical blade outer rim with feeding cylinder inner wall；It is described It sieves barrel side wall and is equipped with several sieve pores, the gear cylinder is located at screening bucket periphery.

This programme has the beneficial effect that:

(1) temperature in feeding cylinder sidewall and feeding cylinder can be made to increase when heating member works, wet glass putty enters charging After cylinder, heat rapid evaporation is can be absorbed in the water being mixed in glass putty, and compared with natural drying, the glass putty dry time needed is more Short, the total time that glass putty screening needs is reduced, and the screening efficiency of glass putty is higher.

(2) it sieves in bucket rotation process, fixed helical blade rotates with it with screening bucket, promotes into feeding cylinder Glass putty is moved into screening bucket.Wet glass putty is liable to stick on feeding cylinder inner wall, due to the outer rim and charging of helical blade Cylinder inner wall is affixed, therefore the glass putty for being attached to feeding cylinder inner wall can be made to slide with respect to feeding cylinder inner wall when helical blade rotation, Guarantee that the glass putty entered in feeding cylinder can enter in screening bucket to be sized.

Preferred embodiment one sieves bucket outer wall and is fixed with axial--flow blading as the further improvement to base case.Screening When bucket rotation, the axial--flow blading rotation being fixed on screening bucket promotes the gas kept off in cylinder to flow along the vertical direction, flowing Gas drives the glass putty movement dropped out from screening bucket, since flowing to for the gas in gear cylinder is identical, therefore drops out from screening bucket Glass putty the direction of motion it is identical, it is convenient that the glass putty screened out is collected, avoid glass putty from being scattered in gear cylinder outer and can not receive Collection, to reduce loss of the glass putty in screening process.

Preferred embodiment two, as the further improvement to preferred embodiment one, axial--flow blading is located at below gear cylinder, and keeps off cylinder Periphery is equipped with the outer cylinder fixed with rack, is fixed with the refrigerator pipe being connected to outer cylinder on the outer cylinder.Cold air enters from refrigerator pipe In space between outer cylinder and gear cylinder, when axial--flow blading rotates, the gas kept off in cylinder moves in the same direction with cold air.Due to heating member The temperature for the glass putty for being dried to the glass putty in feeding cylinder, therefore dropping out from screening bucket is higher, cold air and the glass putty screened out Contact, cools down to glass putty.Gear cylinder is located between refrigerator pipe and screening bucket, and the cold air for entering outer cylinder from refrigerator pipe will not be direct It contacts, the glass putty just dropped out from screening bucket can be blown to outside outer cylinder to avoid cold air with the glass putty just dropped out from screening bucket, Reduce the loss in glass putty screening process.

Preferred embodiment three, as the further improvement to preferred embodiment two, outer cylinder bottom is lower than axial--flow blading, described cold Tracheae is higher than axial--flow blading close to outer cylinder one end.When axial--flow blading moves downward the gas in outer cylinder, cold air and glass putty It can contact with each other, then move downward simultaneously, at this time flowing of the outer cylinder lower part to gas and glass putty when moving to below gear cylinder Play the role of guiding, facilitates the collection of glass putty.

Preferred embodiment four, as the further improvement to preferred embodiment three, axial--flow blading surface is fixed with buffer layer.Sieve The glass putty separated can pass through axial--flow blading, and glass putty is easy to be in contact with axial--flow blading, and buffer layer plays buffering and makees at this time With deformation occurs when glass putty being avoided to contact with axial--flow blading or is worn, the shape of holding powder particles spherical shape, and glass putty Performance is best when particle is spherical in shape.

Preferred embodiment five, as the further improvement to base case, helical blade surface is fixed with water absorption layer.Wet Glass putty contacts after entering feeding cylinder with helical blade, and water absorption layer is contacted with wet glass putty at this time, and the water in glass putty is by water absorption layer It absorbs, the water in glass putty is reduced, and the drying efficiency of glass putty further increases.

Preferred embodiment six, as the further improvement to base case, actuator is variable speed electric motors, particularly.The output of variable speed electric motors, particularly When revolving speed changes, the revolving speed for sieving bucket changes, and sieves the glass putty in bucket with screening bucket rotation, therefore when the revolving speed of screening bucket changes When, the glass putty in screening bucket, relative to screening bucket side walls, avoids the biggish powder particles of partial size under effect of inertia Blocking sieve pore for a long time.

Preferred embodiment seven sieves bucket inner wall and is fixed with several flexible convex blocks as the further improvement to preferred embodiment six. Glass putty is hit relative in screening barrel side wall sliding process with flexible convex block, and the glass putty of conglomeration can disperse, the tin of conglomeration The powder particles that partial size is less than the aperture of sieve pore in powder can pass through sieve pore.

Detailed description of the invention

Fig. 1 is cross-sectional view of the utility model for the screening plant embodiment of glass putty production；

Fig. 2 is the enlarged drawing in Fig. 1 at A.

Specific embodiment

Utility model will be further described in detail below with reference to the attached drawings and specific embodiments:

Appended drawing reference are as follows: staving 1, sieve pore 11, flexible convex block 12, supporting block 13, axial--flow blading 14, buffer layer 15, branch Dagger 16, link block 17, slag notch 18, connecting rod 19, actuator 2, feeding cylinder 3, heating member 31, helical blade 4, water absorption layer 41, cylinder 5, outer cylinder 6, refrigerator pipe 61 are kept off.

For the screening plant of glass putty production, including rack (being not drawn into attached drawing), as shown in Figure 1, along vertical in rack Direction is equipped with feeding cylinder 3, screening bucket, gear cylinder 5 and outer cylinder 6, and screening bucket includes staving 1 and connecting rod 19, welds at the top of connecting rod 19 It connects in 1 bottom of staving, feeding cylinder 3 is located at the top of staving 1, and 3 bottom of feeding cylinder is equipped with downward opening guide groove, on staving 1 End is located in guide groove, and feeding cylinder 3 and staving 1 are rotatablely connected.3 bottom of feeding cylinder is connected to staving 1, and gear cylinder 5 is located at outside staving 1 In week, outer cylinder 6 is located at gear 5 periphery of cylinder, and feeding cylinder 3, gear cylinder 5 and outer cylinder 6 weld on the rack.6 top of outer cylinder, which is equipped with, to be run through The refrigerator pipe 61 of 6 left wall of outer cylinder, 61 right end of refrigerator pipe and outer cylinder 6 are glued, and left end is connected to extraneous cold air manufacturing device.

3 side wall of feeding cylinder is fixed with heating member 31, and the heating member 31 in the present embodiment is adding thermal resistance silk screen, heating member 31 The glass putty entered in feeding cylinder 3 is heated when work, promotes mixed water evaporation in glass putty, keeps glass putty dry.Staving 1 pushes up Portion is set there are three link block 17, and link block 17 is welded on 1 side wall of staving close to screening barrel side wall one end；Along perpendicular in feeding cylinder 3 Histogram is welded on link block 17 far from 1 side wall side of staving to support column 16,16 bottom of support column is coaxially provided with.On support column 16 Rack is run through at end, and 16 upper end of support column is greater than the supporting block 13 of support column 16 integrally formed with diameter, and supporting block 13 is located at rack Top is simultaneously connect with gantry rotation, and rack is supported supporting block 13, and supporting block 13 plays branch to support column 16 and screening bucket Support effect.Rack is equipped with actuator 2, and the actuator 2 in the present embodiment is variable speed electric motors, particularly, and actuator 2 is bolted on In rack, the output shaft of actuator 2 at the top of shaft coupling and support column 16 by connecting, and support column 16 is under the action of actuator 2 Rotation.

The helical blade 4 being affixed in feeding cylinder 3 equipped with outer rim and 3 inner wall of feeding cylinder, helical blade 4 are welded on support column 16 On side wall.As shown in connection with fig. 2,4 upper surface of helical blade, which is glued, water absorption layer 41, and the water absorption layer 41 in the present embodiment is high water absorption Resin sheet, into feeding cylinder 3 glass putty pass through helical blade 4 when, the water being mixed in glass putty is inhaled into water absorption layer 41.

1 side wall of staving is equipped with several sieve pores 11, and the aperture of sieve pore 11 is 38um in the present embodiment, and the splicing of 1 inner wall of staving has Several flexibility convex blocks 12, the flexible convex block 12 in the present embodiment are rubber block, and glass putty occurs after entering staving 1 with flexible convex block 12 It hits, the glass putty dispersion of conglomeration.1 bottom of staving is equipped with slag notch 18 and can close the lid of slag notch 18, opens slag notch 18 Afterwards, the powder particles that partial size is greater than 11 aperture of sieve pore are dropped out from slag notch 18.

Key connection has the axial--flow blading 14 for being located at gear cylinder 5 downside in connecting rod 19, when staving 1 rotates, connecting rod 19 with Screening bucket rotation, axial--flow blading 14 with staving 1 rotate, so that the gas in outer cylinder 6 is flowed downward.On axial--flow blading 14 Surface glue is connected to buffer layer 15, and the buffer layer 15 in the present embodiment is sheet rubber.

When screening plant in the present embodiment sieves glass putty, first manually glass putty collection device is connected to 6 bottom of outer cylinder, and Actuator 2 is opened, actuator 2 drives support column 16 to rotate, and staving 1 rotates with it, and axial--flow blading 14 rotates, shape in outer cylinder 6 At the air-flow to flow downward, the cold air kept off between gas and outer cylinder 6 between cylinder 5 and staving 1 and gear cylinder 5 flows downward.So Heating member 31 is opened manually afterwards and is put into wet glass putty in feeding cylinder 3 above feeding cylinder 3, wet glass putty falls in spiral On blade 4, mixed water is contacted with water absorption layer 41 in glass putty, and water is inhaled into water absorption layer 41.Heating member 31 opens laggard barrel 3 Temperature in side wall and feeding cylinder 3 increases, the heat of vaporization being mixed in the water absorption feeding cylinder 3 in the glass putty in feeding cylinder 3, tin Dried bean noodles is dry.

In 4 rotation process of helical blade, dry glass putty is dropped downward into staving 1 in feeding cylinder 3.Glass putty in staving 1 By centrifugal action to the Slideslip close to 1 side wall of staving, the powder particles that partial size is less than 11 aperture of sieve pore pass through sieve pore 11, drop out staving 1.The glass putty of staving 1 is dropped out as air-flow downward between gear cylinder 5 and staving 1 moves downward, glass putty moves to It is contacted behind 5 lower section of gear cylinder with the cold air flowed down between outer cylinder 6 and gear cylinder 5, cold air cools down glass putty, the glass putty screened out Dropped out from 6 bottom end of outer cylinder, into glass putty collection device in be collected.Slag notch 18 is opened manually after the completion of screening, partial size is greater than The glass putty in 11 aperture of sieve pore is dropped out from slag notch 18.

Above-described is only preferred embodiments of the present invention, it is noted that for those skilled in the art For, without departing from the concept of the premise utility, several modifications and improvements can also be made, these also should be considered as this The protection scope of utility model, these all will not influence the effect and patent practicability of the utility model implementation.This is practical new Technology, shape, the construction portion of the omitted description of type are well-known technique.

Claims (8)

1. the screening plant for glass putty production, which is characterized in that including rack, be equipped with charging in the rack along the vertical direction Cylinder, screening bucket and gear cylinder, the feeding cylinder is located above screening bucket and is connected to screening bucket, and feeding cylinder is fixed with rack, institute It states feeding cylinder sidewall and is fixed with heating member；The screening bucket is connect with gantry rotation, and screening bucket is rotatablely connected with feeding cylinder simultaneously, The rack is equipped with the actuator that can drive screening bucket rotation, and being rotatably connected in the feeding cylinder can be with screening bucket rotation Helical blade, the helical blade outer rim are affixed with feeding cylinder inner wall；The screening barrel side wall is equipped with several sieve pores, the gear cylinder Positioned at screening bucket periphery.

2. the screening plant according to claim 1 for glass putty production, which is characterized in that the screening bucket outer wall is fixed There is axial--flow blading.

3. the screening plant according to claim 2 for glass putty production, which is characterized in that the axial--flow blading is located at It keeps off below cylinder, and keeps off cylinder periphery and be equipped with the outer cylinder fixed with rack, be fixed with the refrigerator pipe being connected to outer cylinder on the outer cylinder.

4. the screening plant according to claim 3 for glass putty production, which is characterized in that the outer cylinder bottom is lower than axis Streaming blade, the refrigerator pipe are higher than axial--flow blading close to outer cylinder one end.

5. the screening plant according to claim 4 for glass putty production, which is characterized in that the axial--flow blading surface It is fixed with buffer layer.

6. the screening plant according to claim 1 for glass putty production, which is characterized in that the helical blade surface is solid Surely there is water absorption layer.

7. the screening plant according to claim 1 for glass putty production, which is characterized in that the actuator is speed change electricity Machine.

8. the screening plant according to claim 7 for glass putty production, which is characterized in that the screening bucket inner wall is fixed There are several flexible convex blocks.