CN215757660U - Short-circuit machine for discharging electrolytic bath - Google Patents

Abstract

The utility model provides a short-circuit machine for discharging an electrolytic cell, which comprises a movable bottom frame, wherein a first lifting mechanism is arranged on the bottom frame, and the lifting end of the first lifting mechanism is connected with a conductive plate. And two ends of the current-conducting plate are respectively provided with a clamping mechanism which can clamp and loosen two electrolytic tank conducting bars at two ends of the current-conducting plate and two sides of the electrolytic tank. The clamping mechanism comprises an upper clamping plate, a lower clamping plate and a second lifting mechanism; the upper clamping plate is fixed on the conductive plate; the fixed end of the second lifting mechanism is connected with the conductive plate or the upper clamping plate, and the lifting end of the second lifting mechanism is rotatably connected with the lower clamping plate; the lower clamping plate rotates to switch between being located below the upper clamping plate and being located below the upper clamping plate. The short-circuit machine can be pushed to move by a driving mechanism or manually, so that short-circuit of different electrolytic tanks is realized.

Description

Short-circuit machine for discharging electrolytic bath

Technical Field

The utility model belongs to the field of lead electrolysis, and particularly relates to a short circuit machine for discharging an electrolytic cell.

Background

Lead electrolysis workshop is after the electrolysis of a period of time, the crude lead on the anode strip can take off impurity and adhere to and form the smart lead on the negative plate, need change the negative and positive plate in the electrolysis trough of accomplishing electrolysis work this moment, all electrolysis troughs are in the tandem state, if hang out the negative and positive plate, then all the other electrolysis troughs will stop the electrolysis, seriously influence production efficiency, so need carry out the short circuit with the electrolysis trough that the copper will be going out of the groove, guarantee all the other electrolysis troughs normal operating, what used at present is the driving when going out of the groove, hang up the copper, carry out the short circuit to it. The method affects the tank outlet efficiency on one hand, and can be eliminated along with the gradual use of the full-automatic travelling crane on the other hand.

SUMMERY OF THE UTILITY MODEL

The utility model provides a short-circuit machine for discharging an electrolytic cell.

The object of the utility model is achieved in the following way: the utility model provides an electrolysis trough goes out short circuit machine for groove, includes the chassis that can remove, set up first elevating system on the chassis, the current conducting plate is connected to first elevating system's lift end.

And two ends of the current-conducting plate are respectively provided with a clamping mechanism which can clamp and loosen two electrolytic tank conducting bars at two ends of the current-conducting plate and two sides of the electrolytic tank.

The clamping mechanism comprises an upper clamping plate, a lower clamping plate and a second lifting mechanism; the upper clamping plate is fixed on the conductive plate; the fixed end of the second lifting mechanism is connected with the conductive plate or the upper clamping plate, and the lifting end of the second lifting mechanism is rotatably connected with the lower clamping plate; the lower clamping plate rotates to switch between being located below the upper clamping plate and being located below the upper clamping plate.

The second lifting mechanism is a screw rod mechanism, the lower end of a screw rod of the screw rod mechanism is fixedly or rotationally connected with the upper clamping plate, and the upper end of the screw rod is provided with a hand wheel; the screw rod is in threaded connection with a lower clamping plate rotating frame moving on the screw rod; the lower clamping plate rotating frame is rotatably connected with the lower clamping plate through the rotating shaft.

The lower clamping plate rotating frame is rotationally connected with the lower clamping plate fixing frame through the rotating shaft; the lower clamping plate is fixed on the lower clamping plate fixing frame so as to realize the rotary connection between the lower clamping plate and the lower clamping plate rotating frame; and a detachable positioning shaft for fixing the lower clamping plate is arranged between the lower clamping plate rotating frame and the lower clamping plate fixing frame.

The lifting end of the first lifting mechanism is connected with the conductive plate through a chain.

Wheels are arranged below the bottom frame, and handrails are arranged on the bottom frame; the chassis is manually pushed or a driving mechanism drives the wheels to rotate.

The utility model has the beneficial effects that: the short circuit machine is provided with a current conducting plate which can be driven by a first lifting mechanism to lift, the short circuit machine is pushed to an electrolysis trough position needing short circuit, and the first lifting mechanism drives the current conducting plate to descend until two ends of the current conducting plate are connected with two electrolysis trough conducting bars to realize current conduction. The short-circuit machine can be pushed to move by a driving mechanism or manually, so that short circuit of different electrolytic tanks is realized. The lower clamping plate of the clamping mechanism of the utility model can rotate so as to be switched between two different positions, and avoids the position interference with the conductive strips of the electrolytic cell in the descending process of the clamping mechanism.

Drawings

Fig. 1 is a schematic diagram of the working state of the short-circuiting machine.

Fig. 2 is a side view of fig. 1.

Fig. 3 is a front view of fig. 1.

Fig. 4 is a first state of the clamping mechanism.

Fig. 5 is a side view of fig. 4.

Fig. 6 is a second state of the clamping mechanism.

Fig. 7 is a side view of fig. 6.

Wherein, 1 is a bottom frame, 2 is a first lifting mechanism, 3 is a conductive plate, 4 is an electrolytic bath, 5 is an electrolytic bath conductive strip, 6 is a clamping mechanism, 60 is an upper clamping plate, 61 is a lower clamping plate, 62 is a lead screw, 63 is a hand wheel, 64 is a lower clamping plate rotating frame, 65 is a lower clamping plate fixing frame, 66 is a positioning shaft, 67 is a rotating shaft, 7 is a chain, and 8 is a handrail.

Detailed Description

In the present invention, unless otherwise specifically defined and limited, technical terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the present invention pertains. The terms "connected", "fixed", "arranged" and the like are to be understood in a broad sense, and may be fixedly connected, detachably connected or integrated; can be directly connected or indirectly connected through an intermediate medium; either mechanically or electrically. Unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features, or indirectly contacting the first and second features through intervening media. Furthermore, a first feature may be "on" or "over" or "above" a second feature, and the like, may be directly on or obliquely above the second feature, or may simply mean that the first feature is at a higher level than the second feature. A first feature "under" or "beneath" a second feature may be directly under or obliquely under the first feature or may simply mean that the first feature is at a lesser level than the second feature. Relational terms such as first, second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Terms used in the description such as "center", "lateral", "longitudinal", "length", "width", "thickness", "height", "front", "rear", "left", "right", "up", "down", "vertical", "horizontal", "top", "bottom", "inner", "outer", "axial", "radial", "circumferential", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation and be operated.

The technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings and specific embodiments. As shown in fig. 1-7, the short-circuiting machine for discharging the electrolytic cell comprises a movable base frame 1, wherein a first lifting mechanism 2 is arranged on the base frame 1, and the lifting end of the first lifting mechanism 2 is connected with a conductive plate 3. Two sides of each electrolytic cell 4 are respectively provided with an electrolytic cell conductive strip 5 which can conduct electricity; electrolyte is arranged in the electrolytic cell 4; the two ends of the cathode plate and the anode plate are respectively lapped on the conducting strips 5 of the electrolytic tank. A plurality of electrolysis cells 4 are connected in series by electrolysis cell conductive strips 5 and cathode and anode plates. When the cathode plate and the anode plate of one of the electrolytic tanks 4 are lifted, two electrolytic tank conducting bars 5 of the electrolytic tank 4 need to be connected to ensure that the electrolysis of the other electrolytic tanks 4 is normally carried out. The short circuit machine is provided with a conductive plate 3 which is driven by a first lifting mechanism 2 to lift, the short circuit machine is pushed to an electrolytic tank 4 position needing short circuit, and the first lifting mechanism 2 drives the conductive plate 3 to descend until two ends of the conductive plate 3 are connected with two electrolytic tank conductive strips 5 to realize conduction. The short-circuit machine can be pushed by a driving mechanism or manually to move, so that short circuit of different electrolytic tanks 5 is realized.

Furthermore, two clamping mechanisms 6 capable of clamping and loosening the two ends of the conductive plate 3 and two electrolytic tank conducting bars 5 on two sides of the electrolytic tank 4 are respectively arranged at two ends of the conductive plate 3. The two clamping mechanisms 6 are used for clamping the two ends of the conducting plate 3 and the electrolytic cell conducting bars 5 below the corresponding end conducting plate 3, so as to ensure the stable connection between the conducting plate 3 and the electrolytic cell conducting bars 5. The structure of the clamping mechanism 6 may be various as long as the corresponding function is achieved.

The clamping mechanism 6 comprises an upper clamping plate 60, a lower clamping plate 61 and a second lifting mechanism; the upper clamping plate 60 is fixed to the conductive plate 3; the fixed end of the second lifting mechanism is connected with the conductive plate 3 or the upper clamping plate 60, and the lifting end of the second lifting mechanism is rotatably connected with the lower clamping plate 61; the lower clamping plate 61 rotates to switch between being located below the upper clamping plate 61 and being located below the upper clamping plate 60. The lower clamping plate 61 can be rotated manually and then fixed by a limiting mechanism. Lower clamping plate 61 also can drive through actuating mechanism and rotate, for example linear driving mechanism such as electric putter or cylinder, electric putter one end is articulated second elevating system's lift end, the other end is articulated lower clamping plate 61, electric putter is flexible to be realized lower clamping plate 61's rotation and spacing. The non-lower position of the upper clamping plate 60 is mainly referred to as a rear position.

The second lifting mechanism is a screw rod mechanism, the lower end of a screw rod 62 of the screw rod mechanism is fixedly or rotatably connected with the upper clamping plate 60, and the upper end of the screw rod 62 is provided with a hand wheel 63; the screw rod 62 is in threaded connection with a lower clamping plate rotating frame 64 which moves on the screw rod 62; the lower clamping plate rotating frame 64 is rotatably connected with the lower clamping plate 61 through the rotating shaft 67.

The lower clamping plate rotating frame 64 is rotationally connected with the lower clamping plate fixing frame 65 through the rotating shaft 67; the lower clamping plate 61 is fixed on the lower clamping plate fixing frame 65 so as to realize the rotary connection between the lower clamping plate 61 and the lower clamping plate rotating frame 64; a detachable positioning shaft 66 for fixing the lower clamping plate 61 is arranged between the lower clamping plate rotating frame 64 and the lower clamping plate fixing frame 65. The lower clamping plate fixing frame 65 and the lower clamping plate rotating frame 64 are respectively provided with a positioning hole, and the positioning shaft 66 penetrates through the corresponding positioning hole to fix the position of the lower clamping plate fixing frame 65. Here, the positioning shaft 66 may be a fixing mechanism such as a screw bolt, and the shape is not limited to a specific one as long as it performs a fixing function. Due to the gravity of the lower clamping plate 61 and the lower clamping plate fixing frame 65, when the lower clamping plate 61 is located at a position below the upper clamping plate 60, the state is stable, and the positioning shaft 66 may not be provided for fixing. However, the lower clamping plate 61 is rotated to a position behind the upper clamping plate 60 and must be fixed by the positioning shaft 66. The lower clamping plate fixing frame 65 is provided with a handle, so that a person can conveniently lift and rotate the lower clamping plate. The lower clamping plate 61 of the clamping mechanism 6 of the utility model can be rotated so as to switch between two different positions, avoiding the interference of the positions with the conducting bars 5 of the electrolyzer during the lowering of the clamping mechanism 6.

The lifting end of the first lifting mechanism 2 and the conductive plate 3 can be connected by a chain 7, and generally can be connected by two chains 7. The chain 7 has a certain movable margin to adapt to the height variation of the conductive strip 5 of the electrolyzer 4 and the relative variation with the short-circuiting machine. The first lifting mechanism 2 may be a conventional lifting mechanism, such as a screw-nut mechanism driven by a motor, and belongs to the prior art, and the structure will not be described in detail. The driving method can adopt the prior art driving method. A button can be arranged on the chassis 1 to manually control the starting and stopping of the first lifting mechanism 2. The conductive plate is preferably a copper plate with good conductivity. Wheels are arranged below the bottom frame 1, and a handrail 8 is arranged on the bottom frame 1; the chassis 1 is manually pushed or a driving mechanism drives the wheels to rotate.

In the specific implementation: pushing the handrail 8 moves the short connecting machine to the side of the electrolytic cell 4 waiting to exit. The lowering button controlling the first lifting mechanism 2 is pressed until the chain 7 is in a slack condition, at which time the conductive plate 3 is completely placed on the conductive strip 5 of the cell. The clamping mechanism 6 is operated to clamp between the conductive plate 3 and the cell conductive strip 5 to ensure conductivity. And waiting for the automatic traveling crane to replace the cathode plate and the anode plate. After the replacement is completed, the clamping mechanism 6 is released, the lifting button is pressed, and the first lifting mechanism 2 is lifted until the conductive plate 3 reaches a safe height. And pushing the short connecting machine to the side surface of the next motor groove 4, and circulating the steps.

When the clamping mechanism 6 needs to clamp, one hand holds the handle, the other hand pulls out the positioning shaft 66, and the lower clamping plate fixing frame 65 rotates until the lower clamping plate 61 is positioned below the upper clamping plate 60. The hand wheel 63 is rotated so that the lower clamping plate 61 is moved upward, and clamps the conductive plate 3 together with the upper clamping plate 60. When the clamping mechanism 6 is released, firstly, the hand wheel 63 is rotated reversely, the lead screw 62 rotates to drive the lower clamping plate rotating frame 64 to descend, and the lower clamping plate 61 is driven to descend. The lower clamping plate holder 65 is rotated to a fixed position and the positioning shaft 66 is inserted.

The features of the embodiments described above may be arbitrarily combined, and the combination of the features is not contradictory, and should be considered as a range described in the present specification. The technical solution according to the present invention and equivalents or changes thereof, as well as several changes and modifications made therein, should also be considered as the protection scope of the present invention without departing from the overall concept of the present invention.

Claims (7)

1. The utility model provides an electrolysis trough goes out groove and uses short circuit machine which characterized in that: the device comprises a movable underframe, wherein a first lifting mechanism is arranged on the underframe, and the lifting end of the first lifting mechanism is connected with a conductive plate.

2. The short-circuiting machine for discharging the electrolytic cell according to claim 1, wherein: and two ends of the current-conducting plate are respectively provided with a clamping mechanism which can clamp and loosen two electrolytic tank conducting bars at two ends of the current-conducting plate and two sides of the electrolytic tank.

3. The short-circuiting machine for discharging the electrolytic cell according to claim 2, wherein: the clamping mechanism comprises an upper clamping plate, a lower clamping plate and a second lifting mechanism; the upper clamping plate is fixed on the conductive plate; the fixed end of the second lifting mechanism is connected with the conductive plate or the upper clamping plate, and the lifting end of the second lifting mechanism is rotatably connected with the lower clamping plate; the lower clamping plate rotates to switch between being located below the upper clamping plate and being located below the upper clamping plate.

4. The short-circuiting machine for discharging the electrolytic cell according to claim 3, wherein: the second lifting mechanism is a screw rod mechanism, the lower end of a screw rod of the screw rod mechanism is fixedly or rotationally connected with the upper clamping plate, and the upper end of the screw rod is provided with a hand wheel; the screw rod is in threaded connection with a lower clamping plate rotating frame moving on the screw rod; the lower clamping plate rotating frame is rotatably connected with the lower clamping plate through a rotating shaft.

5. The short-circuiting device for discharging the electrolytic cell according to claim 4, wherein: the lower clamping plate rotating frame is rotationally connected with the lower clamping plate fixing frame through the rotating shaft; the lower clamping plate is fixed on the lower clamping plate fixing frame so as to realize the rotary connection between the lower clamping plate and the lower clamping plate rotating frame; and a detachable positioning shaft for fixing the lower clamping plate is arranged between the lower clamping plate rotating frame and the lower clamping plate fixing frame.

6. A short-circuiting device for tapping an electrolytic cell according to any one of claims 1 to 5, characterised in that: the lifting end of the first lifting mechanism is connected with the conductive plate through a chain.

7. A short-circuiting device for tapping an electrolytic cell according to any one of claims 1 to 5, characterised in that: wheels are arranged below the bottom frame, and handrails are arranged on the bottom frame; the chassis is manually pushed or a driving mechanism drives the wheels to rotate.

Images