CN211134525U - Welding flux and welding slag classifier - Google Patents

Abstract

The utility model relates to a solder flux dross sorter technical field, the utility model provides a solder flux dross classifier, conveying mechanism including the slope setting, the last first screen cloth that is equipped with of conveying mechanism, the bottom of first screen cloth is equipped with mobilizable categorised box, be equipped with solder flux discharge gate and dust discharge gate on the lateral wall of categorised box, and the solder flux discharge gate sets up with the dust discharge gate relatively, shale shaker and vibration board are installed to the inner chamber of categorised box slope respectively, and the vibration board is located the bottom of shale shaker, the one end of shale shaker is close to first screen cloth, the other end extends to the solder flux discharge gate, the one end of vibration board is close to the solder flux discharge gate, the other end extends to the dust discharge gate, solder flux discharge. The utility model provides a lack solder flux welding slag sorter at present, can't retrieve remaining solder flux in the mixture, cause extravagant problem.

Description

Welding flux and welding slag classifier

Technical Field

The utility model relates to a solder flux welding slag sorter technical field especially relates to a solder flux welding slag sorter.

Background

During welding, a substance capable of melting to form slag (and some gas generation) and having a protective and metallurgical effect on molten metal is called flux.

The flux can be divided into ordinary particle size and fine particle size, wherein the ordinary particle size is most widely used, the flux particle size of the ordinary, non-woven and non-woven flux is 1.6-2.5mm, the fine particle size below 1.4mm is not more than 5%, and the coarse particle size above 2.3mm is not more than 2%.

Welding is widely used in submerged arc welding, and submerged arc welding (including submerged arc welding, electroslag welding, and the like) is an important welding method, has the inherent advantages of stable welding quality, high welding productivity, no arc light, little smoke, and the like, and is a main welding method in the manufacture of important steel structures such as pressure vessels, pipe sections, box-shaped beams and columns, and the like. In recent years, although many new welding methods have been developed with high efficiency and high quality, the application field of submerged arc welding is still not affected at all, and submerged arc welding is about 10% in view of the share of the deposited metal by various welding methods.

At present, in the process of submerged arc welding in hardware manufacturing factories, all welding flux is often not combusted, the residual welding flux on the surface layer of a metal piece is mixed with burnt welding slag and dust to form a mixture, and because a classification device for the mixture such as welding flux slag is lacked, the residual welding flux in the mixture cannot be recovered, so that most welding workers directly clean and dispose the residual welding flux, and the waste of the welding flux is caused.

Therefore, the flux and welding slag classifier is developed, which not only has urgent research value, but also has good economic benefit and industrial application potential, and the classifier is the place and the basis of the power which can be completed by the utility model.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art pointed out above, the utility model discloses the people has carried out the deep research to this, after having paid out a large amount of creative work, thereby accomplished the utility model discloses.

Particularly, the utility model discloses the technical problem that solve is: the utility model provides a welding flux welding slag classifier to solve lack welding flux welding slag sorter at present, can't retrieve remaining welding flux in the mixture, cause extravagant problem.

In order to solve the technical problem, the technical scheme of the utility model is that:

the utility model provides a solder flux welding slag classifier, is including the conveying mechanism that the slope set up, the last first screen cloth that is equipped with of conveying mechanism, the bottom of first screen cloth is equipped with mobilizable categorised box, be equipped with solder flux discharge gate and dust discharge gate on the lateral wall of categorised box, just the solder flux discharge gate with the dust discharge gate sets up relatively, shale shaker and vibration board are installed in the inner chamber of categorised box slope respectively, just the vibration board is located the bottom of shale shaker, the one end of shale shaker is close to first screen cloth, the other end extend to the solder flux discharge gate, the one end of vibration board is close to the solder flux discharge gate, the other end extends to the dust discharge gate, solder flux discharge gate department is equipped with the solder flux collector.

As a modified scheme, conveying mechanism is including carrying barrel, helical blade, rotation axis, feeder hopper, welding slag discharge gate and driving motor, carry the barrel install in the top of categorised box, the bottom of carrying the barrel is equipped with the screen cloth mounting hole, the opening direction orientation of screen cloth mounting hole the inner chamber of categorised box, helical blade install in on the rotation axis, rotation axis rotate install in carry on the barrel, and one end extend to carry the outside of barrel and with driving motor's output shaft links to each other, the feeder hopper install in carry the top of barrel one end and be close to driving motor, the welding slag discharge gate is located carry the bottom of barrel other end, and with the feeder hopper sets up relatively.

As an improved scheme, the first screen is of an arc-shaped structure, the arc-shaped size of the first screen is equal to the inner diameter size of the conveying cylinder, and the first screen is detachably mounted at the screen mounting hole of the conveying cylinder.

As an improved scheme, the vibrating screen comprises a second screen, a support frame, a first vibrator, a first spring and a first base, the second screen is installed at the top of the support frame, the first vibrator is installed at the bottom of the support frame, the support frame is obliquely installed in an inner cavity of the classification box body, the first base is installed on the inner side wall of the classification box body, one end of the first spring is connected with the first base, and the other end of the first spring is connected with the support frame.

As an improved scheme, the vibrating plate comprises a plate body, a second vibrator, a second spring and a second base, wherein the plate body is obliquely arranged in an inner cavity of the classification box body and located at the bottom of the supporting frame, the second vibrator is arranged at the bottom of the plate body, the second base is arranged on the inner side wall of the classification box body, one end of the second spring is connected with the second base, and the other end of the second spring is connected with the plate body.

As an improved scheme, the bottom of the welding flux collector is hinged with a support rod, the support rod is obliquely arranged on the outer side wall of the classification box body, and a reinforcing rod is further arranged between the support rod and the outer side wall of the classification box body;

install a pair of operating handle that sets up relatively on flux collector's the box lateral wall, flux collector is close to one side of categorised box still is connected with one and hangs the ring, on the lateral wall of categorised box and with hang the position that the ring corresponds and install the couple, hang the ring detachable install in on the couple.

As an improved scheme, movable rollers are respectively installed at the bottoms of two ends of the classification box body along the traveling direction, a cleaning opening is further formed in the bottom of the classification box body, and a baffle plate for sealing is arranged at the cleaning opening.

As an improved scheme, push plates for sealing are arranged at the welding flux discharge port and the dust discharge port in a sliding mode.

After the technical scheme is adopted, the beneficial effects of the utility model are that:

by arranging the conveying mechanism, the first screen is arranged on the conveying mechanism, so that the welding flux and dust in the mixture can be separated and fall into the classification box body through the first screen in the conveying process of the mixture, the welding slag in the mixture flows out from the welding slag discharge hole under the driving of the conveying mechanism, the inner cavity of the classification box body is also respectively provided with the vibrating screen and the vibrating plate in an inclined mode, the welding flux and dust in the mixture can be separated again through the vibrating screen, the dust falls onto the vibrating plate at the bottom of the vibrating screen from the vibrating screen and flows out from the dust discharge hole under the action of the vibrating plate, the welding flux reserved on the vibrating screen flows out from the welding flux discharge hole and is collected into the welding flux collector, the classification of the welding flux and the welding slag in the mixture is realized, the recycling of the welding flux is realized, the waste of the welding flux is avoided, and the production;

the conveying mechanism comprises a helical blade, a rotating shaft and the like, and the helical blade and the rotating shaft are more favorable for conveying the mixture;

the first screen is of an arc-shaped structure, and the arc-shaped size of the first screen is equal to the inner diameter size of the conveying cylinder, so that the operation obstruction of the helical blades caused when the first screen is installed on the conveying cylinder is avoided, and meanwhile, the conveying of the mixture in the conveying cylinder is facilitated;

the second screen is used for separating the welding flux and dust, the second screen is arranged on the support frame, the strength of the second screen is enhanced through the support frame, the separation efficiency of the second screen is improved through the arrangement of the first vibrator, and meanwhile the flowability of the welding flux on the second screen is enhanced;

the bottom of the flux collector is hinged with the supporting rod, a suspension ring is arranged on the side face of the flux collector and connected with a hook arranged on the classification box body, under normal conditions, the suspension ring is hung on the hook, so that the flux collector is stabilized on the supporting rod and is positioned below a flux discharge hole, flux is conveniently collected, when the flux collector is fully collected, the suspension ring can be taken down from the hook, the flux collector is turned over to pour the flux in the flux collector into a specified container for reuse, the operation is convenient and rapid, and the strength of the supporting rod is increased by the reinforcing rod arranged between the supporting rod and the classification box body;

the bottom of the classification box body is provided with the roller, so that the movement of the welding flux and welding slag classifier is facilitated, and the bottom of the classification box body is provided with the cleaning port, so that dust falling into the bottom of the classification box body can be regularly treated;

by slidably mounting the push plate at the flux discharge port and the dust discharge port, temporary closing can be performed while handling collected flux and dust.

To sum up, the utility model discloses an above-mentioned technical scheme has solved and has lacked solder flux welding slag sorter at present, can't retrieve remaining solder flux in the mixture, causes extravagant problem.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic structural view of the first screen and the conveying cylinder of the present invention;

FIG. 3 is a schematic structural view of a second screen and a support frame of the present invention;

wherein each numerical designation refers to a particular meaning, element, and/or component, respectively, as follows in the figures.

In the figure: 1. conveying mechanism, 101, conveying cylinder, 102, helical blade, 103, rotating shaft, 104, feeding hopper, 105, welding slag discharge port, 106, driving motor, 107, screen mounting hole, 2, first screen, 3, sorting box, 4, welding flux discharge port, 5, dust discharge port, 6, vibrating screen, 601, second screen, 602, support frame, 603, first vibrator, 604, first spring, 605, first base, 7, vibrating plate, 701, plate body, 702, second vibrator, 703, second spring, 704, second base, 8, welding flux collector, 9, support rod, 10, reinforcing rod, 11, operating handle, 12, suspension ring, 13, hook, 14, roller, 15, cleaning port, 16, baffle, 17, push plate, 18, U-shaped slide rail, 19, connecting sheet.

Detailed Description

The invention will be further described with reference to specific examples. The use and purpose of these exemplary embodiments are to illustrate the invention, not to limit the scope of the invention in any way, and not to limit the scope of the invention in any way.

In the embodiment, as shown in fig. 1 and fig. 2, a solder flux and welding slag classifier includes a conveying mechanism 1 disposed obliquely, a first screen 2 is disposed on the conveying mechanism 1, and the conveying mechanism 1 and the first screen 2 enable the solder flux and dust in a mixture to be separated and fall into a classification box 3 through the first screen 2 in the conveying process of the mixture, the solder slag in the mixture flows out from a solder slag discharge port 105 under the driving of the conveying mechanism 1, a movable classification box 3 is disposed at the bottom of the first screen 2, a solder flux discharge port 4 and a dust discharge port 5 are disposed on the side wall of the classification box 3, the solder flux discharge port 4 is disposed opposite to the dust discharge port 5, the solder flux discharge port 4 is disposed on one side of the classification box 3 in the traveling direction, the dust discharge port 5 is disposed on the other side of the classification box 3 in the traveling direction, and the height of the solder flux discharge port 4 is higher than the, the inner cavity of the classification box body 3 is respectively provided with a vibrating screen 6 and a vibrating plate 7 in an inclined mode, the vibrating plate 7 is located below the bottom of the vibrating screen 6, one end of the vibrating screen 6 is close to the first screen 2, the other end of the vibrating screen extends to the position of the flux discharge hole 4, one end of the vibrating plate 7 is close to the flux discharge hole 4, the other end of the vibrating plate 7 extends to the position of the dust discharge hole 5, a flux collector 8 capable of overturning and discharging is arranged below the flux discharge hole 4, the flux and dust in the mixture can be separated again through the vibrating screen 6, the dust falls onto the vibrating plate 7 at the bottom of the vibrating screen 6 from the vibrating screen 6 and flows out from the dust discharge hole 5 under the action of the vibrating plate 7, the flux remained on the vibrating screen 6 flows out from the flux discharge hole 4 and is collected into the flux collector 8, so that the classification of the flux, the production cost is reduced.

In this embodiment, as shown in fig. 1, the conveying mechanism 1 includes a conveying cylinder 101, a helical blade 102, a rotating shaft 103, a feeding hopper 104, a welding slag discharge port 105 and a driving motor 106, the conveying cylinder 101 is installed on the top of the classification box 3, a screen mounting hole 107 is formed in the bottom of the conveying cylinder 101, an opening direction of the screen mounting hole 107 faces an inner cavity of the classification box 3, the helical blade 102 is installed on the rotating shaft 103, the rotating shaft 103 is rotatably installed on the conveying cylinder 101, and one end of the helical blade extends to the outside of the conveying cylinder 101 and is connected to an output shaft of the driving motor 106, the feeding hopper 104 is installed on the top of one end of the conveying cylinder 101 and is close to the driving motor 106, the welding slag discharge port 105 is installed on the bottom of the other end of the conveying cylinder 101 and is opposite to the feeding hopper 104, when in, the bottom of the conveying cylinder 101 is provided with a screen mounting hole 107, the opening direction of the screen mounting hole 107 faces the inner cavity of the classification box 3, the helical blade 102 is fixedly mounted on the rotating shaft 103 in a welding mode, the rotating shaft 103 is rotatably mounted on the conveying cylinder 101 through a bearing, one end of the rotating shaft extends to the outer side of the conveying cylinder 101 and is connected with an output shaft of the driving motor 106 through a coupler, the coupler is not marked in the figure, the conveying of the mixture is facilitated through the helical blade 102 and the rotating shaft 103, the feed hopper 104 is mounted at the top of one end of the conveying cylinder 101 through a bolt and a connecting sheet 19 and is located at one end of the inclined high position of the conveying cylinder 101 and close to the driving motor 106, the welding slag discharge port 105 is mounted at the bottom of the other end of the conveying cylinder 101 and is arranged opposite.

In this embodiment, as shown in fig. 2, the first screen 2 is an arc-shaped structure, and the arc-shaped size of the first screen 2 is equal to the inner diameter size of the conveying cylinder 101, the first screen 2 is detachably installed at the screen installation hole 107 of the conveying cylinder 101, when the device is used, the first screen 2 is an arc-shaped structure, and the arc-shaped size of the first screen 2 is equal to the inner diameter size of the conveying cylinder 101, thereby preventing the helical blade 102 from being obstructed when the first screen 2 is installed on the conveying cylinder 101, and simultaneously being more beneficial to conveying the mixture in the conveying cylinder 101, the first screen 2 is detachably installed at the screen installation hole 107 of the conveying cylinder 101 through the connecting sheet 19 and the bolt, which facilitates maintenance of the first screen 2, in this embodiment, the aperture of the mesh of the first screen 2 is 2.3-2.5 mm.

In this embodiment, as shown in fig. 1 and 3, the vibrating screen 6 includes a second screen 601, a support 602, a first vibrator 603, a first spring 604 and a first base 605, the second screen 601 is installed on the top of the support 602, the first vibrator 603 is installed on the bottom of the support 602, the support 602 is installed in the inner cavity of the classification box 3 in an inclined manner, the first base 605 is installed on the inner sidewall of the classification box 3, one end of the first spring 604 is connected to the first base 605, and the other end is connected to the support 602, when in use, the second screen 601 is installed on the top of the support 602 through an iron wire, the first vibrator 603 is installed on the bottom of the support 602 through a bolt, the vibrator is common in daily life and belongs to common knowledge of technical personnel in the field, and will not be described herein again, the support 602 is installed in the inner cavity of the classification box 3 in an inclined manner, the first base 605 is fixedly installed on the inner sidewall of the classification, one end of a first spring 604 is mounted on a first base 605 through a bolt, the other end is connected with the bottom of a support frame 602 through a bolt, flux and dust are separated through a second screen 601, the second screen 601 is mounted on the support frame 602, the strength of the second screen 601 is enhanced through the support frame 602, the separation efficiency of the second screen 601 is increased through the arrangement of a first vibrator 603, and the flowability of the flux on the second screen 601 is enhanced, in the embodiment, the aperture of the second screen 601 is 1.4-1.6 mm.

In this embodiment, as shown in fig. 1, the vibrating plate 7 includes a plate 701, a second vibrator 702, a second spring 703 and a second base 704, the plate 701 is obliquely installed in the inner cavity of the classification box 3 and is located at the bottom of the supporting frame 602, the second vibrator 702 is installed at the bottom of the plate 701, the second base 704 is installed on the inner sidewall of the classification box 3, one end of the second spring 703 is connected to the second base 704, and the other end is connected to the plate 701, when in use, the plate 701 is obliquely installed in the inner cavity of the classification box 3 and is located below the bottom of the supporting frame 602, the second vibrator 702 is installed at the bottom of the plate 701 by a bolt, the flow rate of dust on the plate 701 is increased by installing the second vibrator 702, so as to facilitate the dust to flow out from the dust outlet 5, the second base 704 is fixedly installed on the inner sidewall of the classification box 3 by welding, one end of the second spring 703 is installed on, the other end is connected with the bottom of the plate body 701 through a bolt, thereby realizing dust collection processing.

In this embodiment, as shown in fig. 1, the bottom of the flux collector 8 is hinged to a support rod 9, the support rod 9 is obliquely installed on the outer side wall of the classification box 3, and a reinforcing rod 10 is further disposed between the support rod 9 and the outer side wall of the classification box 3;

a pair of operating handles 11 which are oppositely arranged are installed on the outer side wall of the box body of the welding flux collector 8, one side, close to the classification box body 3, of the welding flux collector 8 is further connected with a hanging ring 12, a hook 13 is installed on the outer side wall of the classification box body 3 and corresponds to the hanging ring 12, the hanging ring 12 is detachably installed on the hook 13, when the welding flux collector is used, the bottom of the welding flux collector 8 is hinged with a supporting rod 9 through a pin shaft, the end part of the supporting rod 9 is obliquely installed on the outer side wall of the classification box body 3 in a welding mode, a reinforcing rod 10 is further connected between the supporting rod 9 and the outer side wall of the classification box body 3 in a welding mode, and;

a pair of operating handles 11 which are oppositely arranged are installed on the outer side wall of a box body of the flux collector 8 through bolts, the operating handles 11 are used for facilitating pouring of flux in the flux collector 8, one side, close to the classification box body 3, of the flux collector 8 is connected with a suspension ring 12 through an iron chain, a hook 13 is installed on the outer side wall of the classification box body 3 and corresponds to the suspension ring 12 in a welding mode, in general, the suspension ring 12 is hung on the hook 13, the flux collector 8 is enabled to be stabilized on a supporting rod 9 and located below a flux discharge port 4, collection of the flux is facilitated, when the flux collector 8 is fully collected, the suspension ring 12 can be taken down from the hook 13, the flux in the inside is poured into a designated container to be reused through the flux overturning collector 8, and operation is convenient and rapid.

In this embodiment, as shown in fig. 1, the bottom of the two ends of the classification box 3 along the direction of travel is respectively provided with a movable roller 14, the bottom of the classification box 3 is further provided with a cleaning opening 15, the cleaning opening 15 is provided with a baffle 16 for sealing, when in use, the bottom of the two ends of the classification box 3 along the direction of travel is respectively provided with a roller 14, the movement of the welding flux and welding slag classifier is facilitated by the roller 14, the direction indicated by the arrow in fig. 1 is the direction of travel, the cleaning opening 15 is arranged at the bottom of the classification box 3, and the dust falling into the bottom of the classification box 3 is conveniently and periodically treated.

In this embodiment, as shown in fig. 1, a pushing plate 17 for sealing is slidably mounted at each of the flux discharge port 4 and the dust discharge port 5, when in use, a U-shaped slide rail 18 is mounted at each of the flux discharge port 4 and the dust discharge port 5 in a welding manner, a pushing plate 17 is slidably mounted in the U-shaped slide rail 18, and the pushing plate 17 is used for conveniently sealing the flux discharge port 4 and the dust discharge port 5 so as to process collected dust and flux.

For ease of understanding, the working process of the present embodiment is given below:

as shown in fig. 1, the mixture is introduced into a feed hopper 104, the mixture enters a conveying cylinder 101 through the feed hopper 104, a driving motor 106 is started, the mixture gradually moves towards a welding slag discharge port 105 under the pushing of a spiral blade 102, the mixture is firstly separated when passing through a first screen 2 at the bottom of the conveying cylinder 101, larger-particle welding slag flows out from the welding slag discharge port 105 under the pushing of the spiral blade 102, smaller-particle welding flux and dust fall from meshes of the first screen 2 to a vibrating screen 6 of a classification box body 3 for secondary separation, through the vibrating action of the vibrating screen 6, the smallest-particle dust falls onto the vibrating plate 7 from meshes 601 of the second screen 6 of the vibrating screen 6, and flows out from a dust discharge port 5 under the vibrating action of the vibrating plate 7, the rest welding flux flows into a welding flux collector 8 through the welding flux discharge port 4 for collection, when the welding flux collector 8 is fully collected, the flux discharge port 4 is closed through the push plate 17, the suspension ring 12 on the flux collector 8 is taken down from the hook 13, the flux collector 8 is overturned through the operating handle 11, the flux in the flux collector 8 is poured into a specified container for reuse, and after the pouring is finished, the suspension ring 12 is hung on the hook 13 again.

To sum up can, the utility model discloses an above-mentioned embodiment has solved and has lacked the welding flux welding slag sorter at present, can't retrieve remaining welding flux in the mixture, causes extravagant problem.

It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes, modifications and/or alterations to the present invention may be made by those skilled in the art after reading the technical disclosure of the present invention, and all such equivalents may fall within the scope of the present invention as defined by the appended claims.

Claims (8)

1. A flux and slag classifier is characterized in that: conveying mechanism including the slope setting, the last first screen cloth that is equipped with of conveying mechanism, the bottom of first screen cloth is equipped with mobilizable categorised box, be equipped with solder flux discharge gate and dust discharge gate on the lateral wall of categorised box, just the solder flux discharge gate with the dust discharge gate sets up relatively, shale shaker and vibration board are installed in the inner chamber of categorised box slope respectively, just the vibration board is located the bottom of shale shaker, the one end of shale shaker is close to first screen cloth, the other end extend to the solder flux discharge gate, the one end of vibration board is close to the solder flux discharge gate, the other end extends to the dust discharge gate, solder flux discharge gate department is equipped with the solder flux collector that can overturn and unload.

2. The flux slag classifier as defined in claim 1, wherein: conveying mechanism is including carrying barrel, helical blade, rotation axis, feeder hopper, welding slag discharge gate and driving motor, carry the barrel install in the top of categorised box, the bottom of carrying the barrel is equipped with the screen cloth mounting hole, the opening direction orientation of screen cloth mounting hole the inner chamber of categorised box, helical blade install in on the rotation axis, the rotation axis rotate install in on carrying the barrel, and one end extends to carry the outside of barrel and with driving motor's output shaft links to each other, the feeder hopper install in carry the top of barrel one end and be close to driving motor, the welding slag discharge gate is located carry the bottom of the barrel other end, and with the feeder hopper sets up relatively.

3. The flux slag classifier as defined in claim 2, wherein: first screen cloth is the arc structure, just the arc size of first screen cloth with the internal diameter size of carrying the barrel equals, first screen cloth detachable install in carry the screen cloth mounting hole department of barrel.

4. The flux slag classifier as defined in claim 1, wherein: the vibrating screen comprises a second screen, a support frame, a first vibrator, a first spring and a first base, the second screen is installed at the top of the support frame, the first vibrator is installed at the bottom of the support frame, the support frame is obliquely installed in an inner cavity of the classification box body, the first base is installed on the inner side wall of the classification box body, one end of the first spring is connected with the first base, and the other end of the first spring is connected with the support frame.

5. The flux slag classifier as defined in claim 4, wherein: the vibrating plate comprises a plate body, a second vibrator, a second spring and a second base, wherein the plate body is obliquely arranged in an inner cavity of the classification box body and is located at the bottom of the supporting frame, the second vibrator is arranged at the bottom of the plate body, the second base is arranged on the inner side wall of the classification box body, one end of the second spring is connected with the second base, and the other end of the second spring is connected with the plate body.

6. The flux slag classifier as defined in claim 1, wherein: the bottom of the welding flux collector is hinged with a support rod, the support rod is obliquely arranged on the outer side wall of the classification box body, and a reinforcing rod is arranged between the support rod and the outer side wall of the classification box body;

install a pair of operating handle that sets up relatively on flux collector's the box lateral wall, flux collector is close to one side of categorised box still is connected with one and hangs the ring, on the lateral wall of categorised box and with hang the position that the ring corresponds and install the couple, hang the ring detachable install in on the couple.

7. The flux slag classifier as defined in claim 1, wherein: mobilizable gyro wheel is installed respectively to the both ends bottom along the direction of travel of categorised box, the bottom of categorised box still is provided with the clearance mouth, clearance mouth department is equipped with and is used for confined baffle.

8. The flux slag classifier as defined in claim 1, wherein: and the welding flux discharge hole and the dust discharge hole are both provided with push plates used for sealing in a sliding manner.

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