CN218134836U - Aluminum water distributor for aluminum ingot casting - Google Patents

Abstract

The utility model provides an aluminium water distributor for aluminium ingot pouring relates to aluminium ingot production technical field, include: a support table; the right part of the top end surface of the supporting table is fixedly connected with a fixed seat; a material storage box is fixedly connected in the middle of the top end surface of the fixed seat; the top end surface of the storage box is provided with a feeding groove; a first flow guide frame is fixedly arranged in the middle of the lower part of the left end face of the storage box. The rotation through two auxiliary gears drives two incomplete gears to rotate and enables the auxiliary rack to do reciprocating motion in the process that the auxiliary rack does reciprocating motion through the meshing of the two incomplete gears and the auxiliary rack, the storage barrel can be pushed through the limiting block to do reciprocating motion in the process that the auxiliary rack does reciprocating motion, the aluminum water can be more uniform in the pouring process through the reciprocating motion of the storage barrel, and the problem that the natural flow of the distributed aluminum water in the die can cause the non-uniformity of the aluminum water in the die to cause the inconsistent shape of the formed aluminum ingot is solved.

Description

Aluminum water distributor for aluminum ingot casting

Technical Field

The utility model relates to an aluminium ingot production technical field, in particular to aluminium water distributor for aluminium ingot pouring.

Background

The aluminum ingot production line is usually used for processing the aluminum ingot in the aluminum ingot production process, and an important process in the aluminum ingot production is carried out during the distribution of aluminum water, so that the aluminum water distributor is usually used for distributing the aluminum water for pouring the aluminum ingot by a worker, the distributed aluminum water flows into a mold on an aluminum ingot conveying belt, and the aluminum ingot is formed after the aluminum water in the mold is cooled.

However, in the conventional aluminum water distributor, the aluminum water is usually distributed at a fixed position in the aluminum water distribution process, and the distributed aluminum water naturally flows in the mold to form an aluminum ingot, but the distributed aluminum water naturally flows in the mold, so that the shape of the formed aluminum ingot may be inconsistent due to non-uniformity of the aluminum water in the mold.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides an aluminium water distributor for aluminium ingot pouring, it has the storage vat that can evenly distribute aluminium water, can make first bevel gear drive second bevel gear rotate at telescopic link pivoted in-process, and then the rotation through second bevel gear drives drive gear and rotates, can drive two auxiliary gear and rotate at drive gear pivoted in-process, rotation through two auxiliary gear drives two incomplete gears and rotates, meshing through two incomplete gears and auxiliary rack makes auxiliary rack be reciprocating motion, the in-process that reciprocating motion is to auxiliary rack can promote the storage vat through the stopper and carry out reciprocating motion, reciprocating motion through the storage vat can make aluminium water more even at the in-process of pouring, increase the shaping effect of aluminium ingot.

The utility model provides an aluminium water distributor for aluminium ingot pouring specifically includes: a support table; the right part of the top end surface of the supporting table is fixedly connected with a fixed seat; a material storage box is fixedly connected in the middle of the top end surface of the fixed seat; the top end surface of the storage box is provided with a feeding groove; a first flow guide frame is fixedly arranged in the middle of the lower part of the left end face of the storage box; a flow guide pipe is fixedly arranged at the left part of the bottom end surface of the first flow guide frame; a second flow guide frame is fixedly arranged at the left part of the top end surface of the support table; the second diversion frame is aligned with the diversion pipe; a pouring pipe is fixedly arranged in the middle of the lower part of the left end face of the second flow guide frame; the left side of the support table is provided with a workbench; the front part of the top end surface of the workbench is fixedly connected with a mounting rack in the middle; a driving motor is fixedly arranged on the top end surface of the mounting rack; two support frames are symmetrically and fixedly connected to the top end surface of the workbench; a telescopic rod is rotationally connected in the two support frames; an aluminum ingot conveying belt is arranged between the supporting platform and the workbench.

Optionally, the upper part of the inner wall of the feed chute is connected with a filter plate in a sliding manner; the top end surface of the filter plate is in a rectangular array shape and is fixedly connected with four clamping hooks; the four clamping hooks are clamped on the top end face of the storage box; the upper part of the first flow guide frame is symmetrically and fixedly connected with two first partition plates; the upper part of the second diversion frame is fixedly connected with a second isolation plate.

Optionally, the left part of the outer wall of the telescopic rod is fixedly connected with a driven belt wheel; the left side of the driving motor is coaxially connected with a driving belt wheel; the driving belt wheel is coaxially connected with the driven belt wheel through a transmission belt; the right end face of the storage barrel is connected to the outer wall of the pouring pipe in a sliding manner; the right end face of the telescopic rod is fixedly connected with a storage barrel; the distribution pipes are fixedly arranged on the outer wall of the storage barrel in the middle in an annular array shape; the distribution pipe is aligned with the aluminum ingot conveying belt.

Optionally, a first bevel gear is fixedly connected to the outer wall of the telescopic rod; the rear part of the top end surface of the workbench is fixedly provided with an installation box; a second bevel gear is rotatably connected in the middle of the front end surface of the mounting box; the second bevel gear is meshed with the first bevel gear; the rear side of the second bevel gear is coaxially connected with a transmission gear.

Optionally, two auxiliary gears are symmetrically and rotatably connected in the installation box; the two auxiliary gears are meshed with the transmission gear; the rear end faces of the two auxiliary gears are fixedly connected with an incomplete gear; an auxiliary rack is connected in the installation box in a sliding manner; the two incomplete gears are respectively meshed with the auxiliary racks.

Optionally, a placing fixture block is fixedly connected to the right end face of the auxiliary rack; the left end face of the placing fixture block and the right end face of the placing fixture block are both fixedly connected with a limiting column; the right part of the outer wall of the telescopic rod is fixedly connected with a limiting block; the right end face of the limiting block is fixedly connected to the left end face of one storage barrel; a placing groove is arranged in the middle of the outer wall of the limiting block; a limiting groove is arranged in the middle of the left end face of the placing groove and the right end face of the placing groove; the two limiting columns are respectively connected in the limiting grooves in a sliding mode.

Advantageous effects

The utility model discloses can make the more regular shaping effect that increases the aluminium ingot of the more shape that makes the aluminium ingot of aluminium water distribution at the in-process that carries out the distribution to aluminium water, can clear up the intensity of labour who reduces the staff with the impurity in the aluminium water and the oxidizing slag automatically simultaneously at the in-process of distribution aluminium water.

In addition, can make first bevel gear drive second bevel gear rotate at telescopic link pivoted in-process, and then the rotation through second bevel gear drives drive gear and rotates, can drive two auxiliary gear at drive gear pivoted in-process and rotate, the rotation through two auxiliary gear drives two incomplete gears and rotates, meshing through two incomplete gears and auxiliary rack makes auxiliary rack be reciprocating motion, the in-process that reciprocating motion was done at auxiliary rack can promote the storage vat through the stopper and carry out reciprocating motion, reciprocating motion through the storage vat can make the aluminium water more even at the in-process of pouring, increase the shaping effect of aluminium ingot.

In addition, can filter the impurity that reduces the aluminium aquatic through the filter to the aluminium water of pouring into in the feed chute, dismantle the filter through the trip and can make things convenient for the staff to clean and change the filter, can carry out the separation to the oxidizing slag that the aluminium water surface produced at the in-process that carries out the water conservancy diversion to the aluminium water through first division board and second division board, prevent that the oxidizing slag from getting into on the aluminium ingot casting mould along with the aluminium water.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to only some embodiments of the invention and are not intended to limit the invention.

In the drawings:

fig. 1 is an axial structural schematic diagram of the present invention.

Fig. 2 is a schematic top view of the present invention.

Fig. 3 is a front view of the present invention.

Fig. 4 is a schematic rear view of the present invention.

Fig. 5 is a schematic axial structure view from above.

Fig. 6 is an enlarged schematic view of fig. 5 a according to the present invention.

List of reference numerals

1. A support table; 101. a fixed seat; 102. a material storage box; 103. a feed chute; 104. a filter plate; 105. a hook is clamped; 106. a first flow guide frame; 107. a first separator plate; 108. a flow guide pipe; 109. a second flow guide frame; 110. a second separator plate; 111. pouring a pipe; 112. a work table; 113. a mounting frame; 114. a drive motor; 115. a driving pulley; 116. a driven pulley; 117. a support frame; 118. a telescopic rod; 119. a limiting block; 120. a storage barrel; 121. a distribution pipe; 122. installing a box; 123. a first bevel gear; 124. a second bevel gear; 125. a transmission gear; 126. an auxiliary gear; 127. an incomplete gear; 128. an auxiliary rack; 129. a placement groove; 130. a limiting groove; 131. a limiting column; 132. placing a clamping block; 2. an aluminum ingot conveying belt.

Detailed Description

In order to make the purpose, solution and advantages of the technical solution of the present invention clearer, the drawings of the specific embodiments of the present invention will be combined hereinafter to clearly and completely describe the technical solution of the embodiments of the present invention. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

Example (b): please refer to fig. 1 to fig. 6:

the utility model provides an aluminium water distributor for aluminium ingot pouring, include: supporting table 1

The right part of the top end surface of the supporting table 1 is fixedly connected with a fixed seat 101; a material storage box 102 is fixedly connected to the center of the top end face of the fixed seat 101; the top end surface of the storage box 102 is provided with a feeding groove 103; a first guide frame 106 is fixedly arranged in the middle of the lower part of the left end face of the storage box 102; a guide pipe 108 is fixedly arranged at the left part of the bottom end surface of the first guide frame 106; a second guide frame 109 is fixedly arranged at the left part of the top end surface of the support table 1; the second diversion frame 109 is aligned with the diversion pipe 108; a pouring pipe 111 is fixedly arranged in the middle of the lower part of the left end face of the second flow guide frame 109; the left side of the support table 1 is provided with a workbench 112; a mounting frame 113 is fixedly connected to the front part of the top end surface of the workbench 112 in the middle; a driving motor 114 is fixedly arranged on the top end surface of the mounting frame 113; two support frames 117 are symmetrically and fixedly connected to the top end surface of the workbench 112; a telescopic rod 118 is rotatably connected in the two support frames 117; an aluminum ingot conveying belt 2 is arranged between the support table 1 and the workbench 112.

Furthermore, according to the embodiment of the present invention, as shown in fig. 1 and 2, a filter plate 104 is slidably connected to the upper portion of the inner wall of the feed chute 103; the top end surface of the filter plate 104 is fixedly connected with four clamping hooks 105 in a rectangular array shape; the four clamping hooks 105 are clamped on the top end surface of the storage box 102; the upper part of the first flow guide frame 106 is symmetrically and fixedly connected with two first partition plates 107; the upper portion fixedly connected with of second water conservancy diversion frame 109 is a second division board 110 to can filter the impurity that reduces the aluminium aquatic through filter 104 to the aluminium water of pouring into in the feed chute 103, dismantle filter 104 through trip 105 and can make things convenient for the staff to clean and change filter 104, can carry out the separation to the oxidizing slag that produces the aluminium water surface at the in-process that carries out the water conservancy diversion to the aluminium water through first division board 107 and second division board 110, prevent that the oxidizing slag from getting into on the aluminium ingot casting mould along with the aluminium water.

In addition, according to the embodiment of the present invention, as shown in fig. 1 and 3, a driven pulley 116 is fixedly connected to the left portion of the outer wall of the telescopic rod 118; a driving pulley 115 is coaxially connected to the left side of the driving motor 114; the driving pulley 115 and the driven pulley 116 are coaxially connected through a transmission belt; the right end face of the storage barrel 120 is connected to the outer wall of the pouring pipe 111 in a sliding manner; the right end face of the telescopic rod 118 is fixedly connected with a storage barrel 120; distribution pipes 121 are fixedly arranged on the outer wall of the storage barrel 120 in a ring array shape in the middle; distribution pipe 121 is adjusted well with aluminium ingot transmission band 2 position to in aluminium water flows into storage vat 120 through watering pipe 111, start driving motor 114 and make and drive driven pulley 116 and rotate, drive telescopic link 118 through driven pulley 116's rotation and rotate, telescopic link 118 pivoted in-process can drive storage vat 120 and rotate. And then the aluminum water flows into the aluminum ingot conveying belt 2 through distribution pipes 121 at different positions through the rotating storage barrel 120, so that the distribution of the aluminum water is completed.

In addition, according to the embodiment of the present invention, as shown in fig. 3, a first bevel gear 123 is fixedly connected to an outer wall of the telescopic rod 118; a mounting box 122 is fixedly mounted at the rear part of the top end surface of the workbench 112; a second bevel gear 124 is rotatably connected in the middle of the front end surface of the mounting box 122; second bevel gear 124 meshes with first bevel gear 123; a transmission gear 125 is coaxially connected to the rear side of the second bevel gear 124, so that the first bevel gear 123 drives the second bevel gear 124 to rotate during the rotation of the telescopic rod 118, and the transmission gear 125 is driven to rotate by the rotation of the second bevel gear 124.

Furthermore, according to the embodiment of the present invention, as shown in fig. 4, two auxiliary gears 126 are symmetrically and rotatably connected in the installation box 122; both the auxiliary gears 126 are engaged with the transmission gear 125; the rear end surfaces of the two auxiliary gears 126 are fixedly connected with an incomplete gear 127; an auxiliary rack 128 is slidably connected in the installation box 122; the two incomplete gears 127 are respectively meshed with the auxiliary rack 128, so that the two auxiliary gears 126 are driven to rotate in the rotating process of the transmission gear 125, the two incomplete gears 127 are driven to rotate through the rotation of the two auxiliary gears 126, and the auxiliary rack 128 reciprocates through the meshing of the two incomplete gears 127 and the auxiliary rack 128.

In addition, according to the embodiment of the present invention, as shown in fig. 5 and 6, a placing block 132 is fixedly connected to the right end surface of the auxiliary rack 128; the left end surface of the placing fixture block 132 and the right end surface of the placing fixture block 132 are both fixedly connected with a limiting column 131; the right part of the outer wall of the telescopic rod 118 is fixedly connected with a limiting block 119; the right end face of the limiting block 119 is fixedly connected to the left end face of one storage barrel 120; a placing groove 129 is formed in the middle of the outer wall of the limiting block 119; a limiting groove 130 is formed in the middle of the left end face of the placing groove 129 and the right end face of the placing groove 129; two spacing posts 131 sliding connection respectively are in spacing groove 130 to the in-process that supplementary rack 128 is reciprocating motion can promote storage vat 120 through stopper 119 and carry out reciprocating motion, and reciprocating motion through storage vat 120 can make the aluminium water more even at the in-process of pouring, increases the shaping effect of aluminium ingot.

The specific use mode and function of the embodiment are as follows:

the utility model discloses pour aluminium water into feed chute 103 in the in-process that uses and can filter the impurity that reduces aluminium water in the aluminium water of pouring into feed chute 103 through filter 104, dismantle filter 104 through trip 105 and can make things convenient for the staff to clean and change filter 104, can carry out the separation to the oxide slag that aluminium water surface produced at the in-process that carries out the water conservancy diversion to aluminium water through first division board 107 and second division board 110, prevent that the oxide slag from getting into on the aluminium ingot casting mould along with aluminium water, aluminium water flows in storage vat 120 through watering pipe 111, start driving motor 114 and make and drive driven pulley 116 and rotate, rotation through driven pulley 116 drives telescopic link 118 and rotates, telescopic link 118 pivoted in-process can drive storage vat 120 and rotate. And then the aluminum water flows into the aluminum ingot transmission belt 2 through the distribution pipes 121 at different positions through the rotating storage barrel 120, and the distribution of the aluminum water is completed, the first bevel gear 123 can drive the second bevel gear 124 to rotate in the rotating process of the telescopic rod 118, and further the transmission gear 125 can be driven to rotate through the rotation of the second bevel gear 124, the two auxiliary gears 126 can be driven to rotate in the rotating process of the transmission gear 125, the two incomplete gears 127 can be driven to rotate through the rotation of the two auxiliary gears 126, the auxiliary rack 128 can reciprocate through the engagement of the two incomplete gears 127 and the auxiliary rack 128, the storage barrel 120 can be pushed to reciprocate through the limiting block 119 in the reciprocating process of the auxiliary rack 128, the aluminum water can be more uniform in the pouring process through the reciprocating motion of the storage barrel 120, and the forming effect of the aluminum ingot can be increased.

Finally, it should be noted that the present invention is generally illustrated by one/a pair of components when describing the position of each component and the matching relationship therebetween, however, it should be understood by those skilled in the art that such position, matching relationship, etc. are also applicable to other components/other pairs of components.

The above description is intended to be exemplary of the present invention, and not to limit the scope of the present invention, which is defined by the claims appended hereto.

Claims (6)

1. An aluminum water distributor for aluminum ingot casting, comprising: a support table (1); the right part of the top end surface of the support table (1) is fixedly connected with a fixed seat (101); a material storage box (102) is fixedly connected to the center of the top end face of the fixed seat (101); a feeding groove (103) is formed in the top end face of the storage box (102); a first flow guide frame (106) is fixedly arranged in the middle of the lower part of the left end face of the storage box (102); a flow guide pipe (108) is fixedly arranged at the left part of the bottom end face of the first flow guide frame (106); a second flow guide frame (109) is fixedly arranged at the left part of the top end surface of the support table (1); the second diversion frame (109) is aligned with the diversion pipe (108); a pouring pipe (111) is fixedly arranged in the middle of the lower part of the left end face of the second flow guide frame (109); a workbench (112) is arranged on the left side of the support table (1); a mounting rack (113) is fixedly connected to the front part of the top end surface of the workbench (112) in the middle; a driving motor (114) is fixedly arranged on the top end surface of the mounting rack (113); two support frames (117) are symmetrically and fixedly connected to the top end face of the workbench (112); a telescopic rod (118) is rotationally connected with the two support frames (117); an aluminum ingot conveying belt (2) is arranged between the support table (1) and the workbench (112).

2. An aluminum water distributor for aluminum ingot casting as set forth in claim 1, wherein: the upper part of the inner wall of the feed tank (103) is connected with a filter plate (104) in a sliding way; the top end surface of the filter plate (104) is in a rectangular array shape and is fixedly connected with four clamping hooks (105); the four clamping hooks (105) are clamped on the top end surface of the storage box (102); the upper part of the first flow guide frame (106) is symmetrically and fixedly connected with two first partition plates (107); the upper part of the second flow guide frame (109) is fixedly connected with a second isolation plate (110).

3. An aluminum water distributor for aluminum ingot casting as set forth in claim 1, wherein: the left part of the outer wall of the telescopic rod (118) is fixedly connected with a driven belt wheel (116); the left side of the driving motor (114) is coaxially connected with a driving belt wheel (115); the driving pulley (115) is coaxially connected with the driven pulley (116) through a transmission belt; the right end face of the storage barrel (120) is connected to the outer wall of the pouring pipe (111) in a sliding manner; the right end face of the telescopic rod (118) is fixedly connected with a storage barrel (120); distribution pipes (121) are fixedly arranged on the outer wall of the storage barrel (120) in the middle in an annular array shape; the distribution pipe (121) is aligned with the aluminum ingot conveying belt (2).

4. An aluminum water distributor for aluminum ingot casting as set forth in claim 1, wherein: a first bevel gear (123) is fixedly connected to the outer wall of the telescopic rod (118); the rear part of the top end surface of the workbench (112) is fixedly provided with an installation box (122); a second bevel gear (124) is rotatably connected in the middle of the front end surface of the mounting box (122); the second bevel gear (124) is meshed with the first bevel gear (123); the rear side of the second bevel gear (124) is coaxially connected with a transmission gear (125).

5. An aluminum water distributor for aluminum ingot casting as set forth in claim 4, wherein: two auxiliary gears (126) are symmetrically and rotatably connected in the mounting box (122); the two auxiliary gears (126) are meshed with the transmission gear (125); the rear end surfaces of the two auxiliary gears (126) are fixedly connected with an incomplete gear (127); an auxiliary rack (128) is connected in the installation box (122) in a sliding manner; the two incomplete gears (127) are respectively meshed with the auxiliary racks (128).

6. An aluminum water distributor for aluminum ingot casting as set forth in claim 5, wherein: a placing fixture block (132) is fixedly connected to the right end face of the auxiliary rack (128); the left end face of the placing clamping block (132) and the right end face of the placing clamping block (132) are fixedly connected with a limiting column (131); the right part of the outer wall of the telescopic rod (118) is fixedly connected with a limiting block (119); the right end face of the limiting block (119) is fixedly connected to the left end face of a storage barrel (120); a placing groove (129) is arranged in the middle of the outer wall of the limiting block (119); a limiting groove (130) is formed in the middle of the left end face of the placing groove (129) and the right end face of the placing groove (129); the two limiting columns (131) are respectively connected in the limiting groove (130) in a sliding manner.

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