CN210965757U - Automatic dacromet dip-coating draining system of feed - Google Patents

Abstract

The utility model discloses an automatic feeding dacromet dip-coating draining system, which comprises a loading turntable, wherein the loading turntable is provided with at least two loading standing grooves for placing dip-coating cage frames, and the bottom wall of each loading standing groove is provided with a supporting spring with a vertical axis; the vibration feeding device is characterized by further comprising a vibration feeding bin arranged on one side of the charging turntable, a vibration feeding port is formed in the lower end, facing the side wall of the charging turntable, of the vibration feeding bin, an overturning baffle is arranged at the vibration feeding port, the lower end of the overturning baffle is hinged with the lower edge of the vibration feeding port, and a hinged shaft of the overturning baffle is in transmission connection with a baffle driving motor; the dip-coating cage frame comprises a loading placing groove and a baffle plate driving motor, and is characterized by further comprising a proximity switch used for sensing the upper end of the dip-coating cage frame in the loading placing groove below the vibration feeding port, wherein the proximity switch is in signal connection with the baffle plate driving motor. The utility model discloses can accurately control the work piece load capacity in the dip-coating cage frame at every turn.

Description

Automatic dacromet dip-coating draining system of feed

Technical Field

The utility model relates to a steel construction material production facility technical field, especially an automatic dacromet dip-coating draining system of feed.

Background

Dacromet is also called Dacromet rust, Gaoke rust, zinc-chromium film and the like, and means that a liquid processing liquid containing zinc sheets, aluminum sheets, chromic anhydride, ethylene glycol and the like is used for coating a metal substrate, and after high-temperature baking, a non-decorative coating film with excellent corrosion resistance is formed on the surface of the metal substrate. The Dacromet coating metal corrosion prevention technology avoids the problem of emission pollution of waste residues, sewage and waste gas generated in the electroplating process, and is a new technology for surface corrosion prevention instead of electrogalvanizing, hot galvanizing and the like.

In the prior art, a workpiece needing to be provided with a dacromet coating is placed in a dip-coating cage frame, then the workpiece in the dip-coating cage frame is placed in a container containing dacromet treatment liquid for dip-coating, finally the dip-coating cage frame is taken out, the redundant dacromet treatment liquid is drained, and the workpiece in the dip-coating cage frame is flatly laid in a tunnel type online baking oven to be heated and dried. The disadvantages of the above operation mode are: generally, the load of the workpiece in the cage is not accurately controlled every time of dip coating, when the load of the workpiece is too small, the production efficiency is affected, and when the load of the workpiece is too large, the workpiece positioned at the top of the dip coating cage may not be sufficiently dip-coated with the dacromet treatment liquid during dip coating operation.

Disclosure of Invention

In order to overcome prior art's not enough, the utility model provides an automatic dacromet dip-coating draining system of feed can accurately control the work piece load capacity in the dip-coating cage frame at every turn to can guarantee production efficiency, can avoid again to be located the work piece at dip-coating cage frame top and fail the problem that abundant dip-coating reaches the dacromet treating fluid.

The utility model provides a technical scheme that its technical problem adopted is:

the automatic feeding Dacromet dip-coating draining system comprises a loading turntable, wherein at least two loading placing grooves for placing a dip-coating cage frame are arranged on the loading turntable, and a supporting spring with a vertical axis is arranged on the bottom wall of each loading placing groove; the vibration feeding device is characterized by further comprising a vibration feeding bin arranged on one side of the charging turntable, a vibration feeding port is formed in the lower end, facing the side wall of the charging turntable, of the vibration feeding bin, an overturning baffle is arranged at the vibration feeding port, the lower end of the overturning baffle is hinged with the lower edge of the vibration feeding port, and a hinged shaft of the overturning baffle is in transmission connection with a baffle driving motor; the dip-coating cage frame comprises a loading placing groove and a baffle plate driving motor, and is characterized by further comprising a proximity switch used for sensing the upper end of the dip-coating cage frame in the loading placing groove below the vibration feeding port, wherein the proximity switch is in signal connection with the baffle plate driving motor.

As a further improvement of the above technical scheme, be provided with eccentric vibrating motor on the vibratory feeding storehouse, just the bottom in vibratory feeding storehouse sets up on the vertical vibrating spring of axis, vibrating spring's lower extreme is fixed to be set up on feeding storehouse base, eccentric vibrating motor also with proximity switch signal connection.

As a further improvement of the technical scheme, a plurality of turntable rollers are arranged at the bottom of the charging turntable, the turntable rollers are circumferentially distributed around the axis of the charging turntable, and the bottoms of the turntable rollers are arranged in an annular rotating track; the side of the loading turntable is provided with a turntable driving wheel, the turntable driving wheel is parallel to the axis of the loading turntable, the roller surfaces of the loading turntable are tightly attached to each other, and the turntable driving wheel is in transmission connection with a turntable driving motor through a speed reducer.

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

the utility model provides an automatic dacromet dip-coating draining system of feed holds up the spring through setting up, will descend when the work piece in the dip-coating cage frame loads basis weight to make proximity switch lose the response target, make the upset baffle turn-up and stop reinforced, can accurately control the work piece loading capacity in the dip-coating cage frame at every turn, thereby can guarantee production efficiency, can avoid the work piece that is located dip-coating cage frame top again to fail the problem that abundant dip-coating reaches the dacromet treating fluid.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic structural diagram of an automatic feeding dacromet dip-coating draining system of the present invention.

Detailed Description

Referring to fig. 1, fig. 1 is a schematic structural diagram of an embodiment of the present invention.

As shown in fig. 1, an automatic feeding dacromet dip-coating draining system comprises a loading turntable 10, wherein at least two loading placement grooves 11 for placing a dip-coating cage frame 20 are arranged on the loading turntable 10, and a supporting spring 12 with a vertical axis is arranged on the bottom wall of each loading placement groove 11; the feeding device is characterized by further comprising a vibratory feeding bin 30 arranged on one side of the charging turntable 10, a vibratory feeding port 31 is formed in the lower end, facing the side wall of the charging turntable 10, of the vibratory feeding bin 30, an overturning baffle 32 is arranged at the vibratory feeding port 31, the lower end of the overturning baffle 32 is hinged to the lower edge of the vibratory feeding port 31, and a hinged shaft of the overturning baffle 32 is in transmission connection with a baffle driving motor 33; the device also comprises a proximity switch 34 used for sensing the upper end of the dipping coating cage frame 20 in the loading and placing groove 11 below the vibration feeding port 31, and the proximity switch 34 is in signal connection with the baffle driving motor 33.

Specifically, be provided with eccentric vibrating motor 35 on the vibratory feeding storehouse 30, just the bottom of vibratory feeding storehouse 30 sets up on the vertical vibrating spring 36 of axis, the lower extreme of vibrating spring 36 is fixed to be set up on feeding storehouse base 37, eccentric vibrating motor 35 also with proximity switch 34 signal connection. A plurality of turntable rollers 13 are arranged at the bottom of the charging turntable 10, the turntable rollers 13 are circumferentially distributed around the axis of the charging turntable 10, and the bottoms of the turntable rollers 13 are arranged in an annular rotating track 14; the side of the loading turntable 10 is provided with a turntable driving wheel 15, the axis of the turntable driving wheel 15 is parallel to the axis of the loading turntable 10, the roller surfaces of the turntable driving wheel 15 and the loading turntable 10 are tightly attached to each other, and the turntable driving wheel 15 is in transmission connection with a turntable driving motor 17 through a speed reducer 16.

Further, the device comprises a Dacromet dip-coating tank, wherein a translation slide rail 21 is arranged above the Dacromet dip-coating tank and the charging turntable 10, a translation slide seat 22 is arranged on the translation slide rail 21, a hoisting rope 23 is arranged on the translation slide seat 22, and a mechanical claw 24 for grabbing the upper end of the dip-coating cage frame 20 is arranged at the lower end of the hoisting rope 23. The dacromet dip coating tank comprises an immersion coating liquid part 41 and a draining receiving part 42 which are arranged along the direction of the translation slide rail 21, wherein the draining receiving part 42 is positioned at the downstream of the immersion coating liquid part 41, and the bottom wall of the draining receiving part 42 is continuously increased from the upstream to the downstream.

In operation, the empty dipping cage 20 is firstly placed on the loading and placing tank 11, when the dipping cage 20 rotates to the position below the vibratory feeding port 31, the upper end of the dipping cage 20 is sensed by the proximity switch 34, and the proximity switch 34 controls the eccentric vibration motor 35 and the baffle driving motor 33 to start to operate: the eccentric vibration motor 35 starts to vibrate, the baffle driving motor 33 rotates the turnover baffle 32, and the vibration feeding port 31 is opened;

as the number of workpieces loaded in the dip-coating cage 20 increases, the dip-coating cage 20 continuously falls against the elastic force of the supporting spring 12 until the proximity switch 34 does not sense the upper end of the dip-coating cage 20, and the proximity switch 34 controls the eccentric vibration motor 35 and the baffle driving motor 33 to stop working: the eccentric vibration motor 35 stops vibrating, and the baffle driving motor 33 rotates the inversion baffle 32 to close the vibration feeding port 31.

After the transferring is completed, the dip-coating cage frame 20 rotates along with the loading and placing groove 11, so that the subsequent dip-coating cage frame 20 in the loading and placing groove 11 is used for loading the workpiece by repeating the above process, meanwhile, the translation slide carriage 22 on the translation slide rail 21 is translated to the position above the dip-coating cage frame 20 of the transferred workpiece, and the upper end of the dip-coating cage frame 20 is grabbed by the mechanical claw 24 — this step can be automatic operation or manual assistance; then the hoisting rope 23 lifts the dip-coating cage frame 20, the translation slide 22 translates to the immersion liquid coating part 41, the dip-coating cage frame 20 descends to perform dip-coating operation, and after dip-coating is completed, the dip-coating cage frame 20 translates to the position above the draining receiving part 42 to perform draining.

While the preferred embodiments of the present invention have been described in detail, it is to be understood that the present invention may be embodied in other forms than those specifically described and that various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention.

Claims (5)

1. An automatic-feeding Dacromet dip-coating draining system is characterized in that: the dip-coating cage comprises a loading turntable (10), wherein at least two loading placing grooves (11) for placing a dip-coating cage frame (20) are formed in the loading turntable (10), and a supporting spring (12) with a vertical axis is arranged on the bottom wall of each loading placing groove (11); the feeding device is characterized by further comprising a vibration feeding bin (30) arranged on one side of the loading turntable (10), a vibration feeding port (31) is formed in the lower end of one side wall, facing the loading turntable (10), of the vibration feeding bin (30), a turnover baffle (32) is arranged at the vibration feeding port (31), the lower end of the turnover baffle (32) is hinged to the lower edge of the vibration feeding port (31), and a hinged shaft of the turnover baffle (32) is in transmission connection with a baffle driving motor (33); the dip coating cage is characterized by further comprising a proximity switch (34) used for sensing the upper end of the dip coating cage frame (20) in the loading and placing groove (11) below the vibration feeding port (31), wherein the proximity switch (34) is in signal connection with the baffle driving motor (33).

2. The automated dosed dycromet dip-coating drain system of claim 1, wherein: be provided with eccentric vibrating motor (35) on vibration feeding storehouse (30), just the bottom of vibration feeding storehouse (30) sets up on vertical vibrating spring (36) of axis, the lower extreme of vibrating spring (36) is fixed to be set up on feeding storehouse base (37), eccentric vibrating motor (35) also with proximity switch (34) signal connection.

3. The automated dosed dycromet dip-coating drain system of claim 1, wherein: a plurality of turntable rollers (13) are arranged at the bottom of the loading turntable (10), the turntable rollers (13) are circumferentially distributed around the axis of the loading turntable (10), and the bottoms of the turntable rollers (13) are arranged in an annular rotating track (14); the side of the loading turntable (10) is provided with a turntable driving wheel (15), the turntable driving wheel (15) and the loading turntable (10) are parallel in axis and the roller surfaces are tightly attached to each other, and the turntable driving wheel (15) is in transmission connection with a turntable driving motor (17) through a speed reducer (16).

4. The automated dosed dycromet dip-coating drain system of claim 1, wherein: the dip-coating device is characterized by further comprising a Dacromet dip-coating pool, a translation sliding rail (21) is arranged above the Dacromet dip-coating pool and between the loading turntables (10), a translation sliding seat (22) is arranged on the translation sliding rail (21), a hoisting rope (23) is arranged on the translation sliding seat (22), and a mechanical claw (24) used for grabbing the upper end of the dip-coating cage frame (20) is arranged at the lower end of the hoisting rope (23).

5. The automated dosed Dacromet dip-coating drain system of claim 4, wherein: the Dacromet dip-coating pool comprises an immersion coating liquid part (41) and a draining receiving part (42) which are arranged along the direction of the translation slide rail (21), wherein the draining receiving part (42) is positioned at the downstream of the immersion coating liquid part (41), and the bottom wall of the draining receiving part (42) is continuously increased from the upstream to the downstream.

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