CN112846163A

CN112846163A - Magnesium alloy casting ladle for continuous exchange of conductor ceramics

Info

Publication number: CN112846163A
Application number: CN202011625039.4A
Authority: CN
Inventors: 刘雪珠
Original assignee: Guangzhou Yiyuanyuan Trading Co ltd
Current assignee: Li Sanyuan
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2021-05-28

Abstract

The invention discloses a magnesium alloy casting ladle for continuous exchange of conductor ceramics, which structurally comprises a supporting rod, a main body and a control panel, wherein the main body is clamped at the bottom end of the supporting rod, the control panel is arranged at the side end of the main body, the main body comprises a casting ladle, a ceramic layer and a blanking block, the blanking block comprises a hollow groove, a trigger block, a return spring, a lower ejector block, a suck-back device and a guide device, the suck-back device comprises a suck-up groove, a tension spring, a suck-up block and a steel wire, the suck-up block comprises a suck-up body, a support column, an elastic rod, an attaching piece and a fixing ring, the trigger block is pressed down by liquid, so that the lower ejector block below the trigger block props against the steel wire, the steel wire drives the material sucking block to move towards the interior of the material sucking groove, the liquid metal arranged at the outer end of the material suction groove is adsorbed, so that the situation that the liquid metal flows down along the outer end of the blanking block is avoided, and the situation of material waste is avoided.

Description

Magnesium alloy casting ladle for continuous exchange of conductor ceramics

Technical Field

The invention relates to the field of conductor ceramics, in particular to a magnesium alloy casting ladle for continuous exchange of conductor ceramics.

Background

The magnesium alloy casting ladle is mainly characterized in that liquefied metal is poured into the magnesium alloy casting ladle, the poured molten metal is cooled and formed through a fixed casting ladle model, so that the forming process is completed, and in the pouring process of the liquefied metal, in order to accelerate cooling heat exchange, conductor ceramic is embedded in the casting ladle, and cooling water is introduced into the casting ladle.

Based on the findings of the inventor, the prior magnesium alloy casting ladle continuously exchanging conductor ceramics mainly has the following defects, such as: when the casting ladle pours the liquefied metal into the model, when the angle of casting ladle slope is less, the liquefied metal can flow down along the outer wall of casting ladle for the liquefied metal attaches at the outer terminal surface of casting ladle, leads to the liquefied metal not can be accurate carry out the cooling shaping in the injection model, causes the condition of extravagant material.

Disclosure of Invention

Aiming at the problems, the invention provides a magnesium alloy casting ladle for continuously exchanging conductor ceramics.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a continuous exchange's of conductor pottery magnesium alloy casting ladle, its structure includes bracing piece, main part, control panel, the bottom block of bracing piece has the main part, the control panel is installed to the side of main part, the main part includes casting package, ceramic layer, unloading piece, the inside of casting package is for cutting open the sky form, the laminating of the inner of ceramic layer has the ceramic layer, the material piece sets up the top front end at the casting package down.

Further, the blanking block comprises an empty groove, a triggering block, a reset spring, a lower top block, a suck-back device and a material guiding device, the empty groove is formed in the rear end of the inner portion of the blanking block, the triggering block is clamped above the empty groove, the reset spring is installed at the bottom end of the triggering block, the lower top block is fixedly embedded at the side end of the bottom of the triggering block, the suck-back device is located at the front end of the inner portion of the blanking block, the material guiding device is fixedly embedded at the tail end of the blanking block, and the reset spring is movably matched with the triggering block.

Further, the suck-back device comprises a material sucking groove, an extension spring, a material sucking block and a steel wire, wherein the material sucking groove is arranged at the front end of the material discharging block and communicated with the empty groove, the extension spring is embedded at the bottom end of the material sucking groove, the material sucking block is clamped in the material sucking groove, one end of the steel wire is embedded at the bottom end of the material sucking block, the other end of the steel wire is connected to the inside of the empty groove, and the extension spring is movably matched with the material sucking block.

Further, inhale the material piece and include material absorption body, support column, elastic rod, laminating piece, solid fixed ring, the support column has been inlayed in the middle of the bottom of material absorption body is positive, the elastic rod is equipped with two, and installs respectively in the both sides end of support column, the side at material absorption block is installed to the laminating piece, and with elastic rod clearance fit, gu fixed ring inlays the bottom at material absorption block, the terminal surface of laminating piece is circular-arc.

Furthermore, the material guiding device comprises three adsorption tanks, a movable tank, a swinging sheet and a rewinding spring, the adsorption tanks are transversely arranged on the upper end face of the material guiding device, the movable tank is located at the rear end of the material guiding device, the swinging sheet is clamped in the movable tank, the rewinding spring is installed at the side end of the swinging sheet, and the rewinding spring is movably matched with the swinging sheet.

Furthermore, the swing piece includes supporter, block axle, guide plate, the side both ends of supporter are equipped with the block axle, block axle and activity groove looks block, the guide plate is equipped with six, and transverse arrangement is in the front end of supporter, the length of guide plate reduces to both ends from the centre gradually.

Furthermore, the guide plate comprises guide blocks, material accumulating grooves and two protruding blocks, the guide blocks are arranged at two ends of the guide plate, the material accumulating grooves are located at the upper end of the guide plate, the protruding blocks are transversely arranged on the upper end face of the material accumulating grooves, and the end face of each guide block is arc-shaped.

Advantageous effects

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the trigger block is pressed downwards by using the liquid metal, so that the lower ejector block below the trigger block props against the steel wire, the steel wire drives the material suction block to move towards the inside of the material suction groove, the liquid metal arranged at the outer end of the material suction groove is adsorbed, the situation that the liquid metal flows downwards along the outer end of the material discharge block is avoided, and the situation of material waste is avoided.

2. According to the invention, the rewinding spring is reset to drive the swinging piece to turn upwards, so that the swinging piece can guide the liquid metal outwards, the situation that the residual liquid metal flows downwards along the outer end of the blanking block after the liquid metal is cast is avoided, and the situation that the material is wasted during casting is avoided.

Drawings

FIG. 1 is a schematic structural diagram of a magnesium alloy casting ladle continuously exchanged with conductor ceramics in a front view.

Fig. 2 is a schematic sectional structure view of the main body of the present invention.

Fig. 3 is a schematic sectional structure view of the blanking block of the present invention.

Fig. 4 is an enlarged structural diagram of a in fig. 3 according to the present invention.

FIG. 5 is a schematic cross-sectional structure view of the material suction block of the present invention.

Fig. 6 is a schematic cross-sectional structure view of the material guiding device of the present invention.

Fig. 7 is a schematic front view of the swing sheet of the present invention.

Fig. 8 is a schematic cross-sectional structure view of the swing piece of the present invention.

In the figure: the device comprises a support rod 1, a main body 2, a control panel 3, a casting ladle 21, a ceramic layer 22, a blanking block 23, an empty groove 231, a trigger block 232, a return spring 233, a lower top block 234, a suck-back device 235, a material guide device 236, a material suction groove a1, a tension spring a2, a material suction block a3, a steel wire a4, a material suction body a31, a support column a32, an elastic rod a33, a laminating sheet a34, a fixing ring a35, an adsorption groove b1, a movable groove b2, a swinging sheet b3, a rewind spring b4, a support body b31, a clamping shaft b32, a guide sheet b33, a guide block c1, a material accumulation groove c2 and a convex block c 3.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows: referring to fig. 1-5, the embodiments of the present invention are as follows:

its structure includes bracing piece 1, main part 2, control panel 3, the bottom block of bracing piece 1 has main part 2, control panel 3 is installed to the side of main part 2, main part 2 includes casting package 21, ceramic layer 22, unloading piece 23, the inside of casting package 21 is for cuing open the empty form, the laminating of ceramic layer 22's the inner has ceramic layer 22, unloading piece 23 sets up the top front end at casting package 21.

The blanking block 23 comprises an empty groove 231, a trigger block 232, a reset spring 233, a lower top block 234, a suck-back device 235 and a material guiding device 236, the empty groove 213 is arranged at the rear end inside the blanking block 23, the trigger block 232 is clamped above the empty groove 231, the reset spring 233 is arranged at the bottom end of the trigger block 232, the lower top block 234 is embedded at the bottom side end of the trigger block 232, the suck-back device 235 is arranged at the front end inside the blanking block 23, the material guiding device 236 is embedded at the tail end of the blanking block 23, the reset spring 233 is movably matched with the trigger block 232, so that the trigger block 232 is pressed down through liquid metal, the trigger block 232 is moved down by contraction of the reset spring 233, and the trigger block 232 can be driven to move up by the reset of the reset spring 233 without the action of the liquid metal.

The suck-back device 235 comprises a suction groove a1, an extension spring a2, a suction block a3 and a steel wire a4, the suction groove a1 is arranged at the front end of the blanking block 23 and is communicated with the empty groove 231, the extension spring a2 is embedded at the bottom end of the suction groove a1, the suction block a3 is clamped in the suction groove a1, one end of the steel wire a4 is embedded at the bottom end of the suction block a3, the other end of the steel wire a4 is connected to the inside of the empty groove 231, the extension spring a2 is movably matched with the suction block a3, and the extension spring a2 is favorable for driving the suction block a3 to move upwards, so that the port of the suction groove a1 is sealed, and the steel wire a4 is straightened.

The suction block a3 comprises a suction body a31, a supporting column a32, an elastic rod a33, two attaching pieces a34 and a fixing ring a35, the supporting column a32 is embedded in the middle of the bottom of the suction body a31, the two elastic rods a33 are respectively installed at two side ends of the supporting column a32, the attaching pieces a34 are installed at the side ends of the suction block a3 and movably matched with the elastic rod a33, the fixing ring a35 is embedded at the bottom end of the suction block a3, the end face of the attaching pieces a34 is arc-shaped, the attaching pieces a34 are attached to the end face of the suction groove a1, the sealing performance of the suction groove a1 is improved, liquid metal can be absorbed inwards, and the situation that the liquid metal flows downwards along the outer end of the lower block 23 is avoided.

Based on the above embodiment, the specific working principle is as follows: when the inclination angle of the casting ladle 21 is not enough to cause the liquid metal to flow downwards along the outer end of the blanking block 23 to cause material waste, the reset spring 233 is movably matched with the trigger block 232, the trigger block 232 is pressed downwards through the liquid metal, the reset spring 233 contracts to enable the trigger block 232 to move downwards, the trigger block 232 can be reset through the reset spring 233 to drive to move upwards without the action of the liquid metal, the lower ejector block 234 arranged at the bottom end of the trigger block 232 can eject the steel wire a4 downwards, so that the suction block a3 is driven to move towards the lower end of the suction groove a1 to absorb the liquid metal at the outer end of the suction groove a1, the outer end of the attaching piece a34 is set to be arc-shaped, the attaching piece a34 is attached to the end face of the suction groove a1, the sealing performance of the suction groove a1 is improved, the liquid metal can be absorbed inwards, and the situation that the liquid metal flows downwards along the blanking block 23 is avoided, so that no waste of material occurs.

Example two: referring to fig. 6-8, the embodiment of the present invention is as follows:

the material guiding device 236 comprises three adsorption grooves b1, a movable groove b2, a swinging sheet b3 and a rewinding spring b4, the adsorption grooves b1 are transversely arranged on the upper end face of the material guiding device 236, the movable groove b2 is located at the rear end of the material guiding device 236, the swinging sheet b3 is clamped with the movable groove b2, the rewinding spring b4 is installed at the side end of the swinging sheet b3, and the rewinding spring b4 is movably matched with the swinging sheet b3, so that the swinging sheet b3 is driven to turn upwards through the resetting of the rewinding spring b4, the swinging sheet b3 can guide the liquid metal outwards, and the liquid metal is prevented from flowing downwards along the outer end of the lower material block 23.

The swinging piece b3 comprises a support body b31, a clamping shaft b32 and guide pieces b33, the clamping shafts b32 are arranged at two ends of the side face of the support body b31, the clamping shafts b32 are clamped with the movable grooves b2, six guide pieces b33 are arranged at the front end of the support body b31, the length of each guide piece b33 is gradually reduced from the middle to two ends, liquid metal is guided to the middle in a concentrated mode, and the situation that the liquid metal flows down along the outer end of the lower material block 23 is avoided.

The guide piece b33 includes water conservancy diversion piece c1, ponding groove c2, protruding piece c3, water conservancy diversion piece c1 sets up the both ends at guide piece b33, ponding groove c2 is located the upper end of guide piece b33, protruding piece c3 is equipped with two, and transversely arranges in the up end of ponding groove c2, the terminal surface of water conservancy diversion piece c1 is circular-arc, is favorable to leading the inner of liquid metal down feed block 23, makes the surplus liquid metal of the liquid metal that has toppled over can not appear along the outer end circumstances of lower feed block 23 downstream.

Based on the above embodiment, the specific working principle is as follows: utilize rewind spring b4 and swing piece b3 clearance fit, can let rewind spring b4 reset and drive swing piece b3 and upwards overturn, make swing piece b3 can outwards lead liquid metal, recycle and set up the length of direction piece b33 to dwindle to both ends by the centre gradually, be favorable to concentrating the inferior tai metal and lead to the centre, the terminal surface that utilizes water conservancy diversion piece c1 sets up to circular-arcly at last, can lead the inner of liquid metal down material piece 23, make the condition that the outer end of material piece 23 flows down can not appear along in the remaining liquid metal of the liquid metal of having emptyd, avoid appearing the condition of extravagant material in the casting.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a continuous exchange's of conductor pottery magnesium alloy casting ladle, its structure includes bracing piece (1), main part (2), control panel (3), the bottom block of bracing piece (1) has main part (2), control panel (3), its characterized in that are installed to the side of main part (2):

the main part (2) is including casting package (21), ceramic layer (22), unloading piece (23), the inside of casting package (21) is for cutting open the empty form, the laminating of the inner of ceramic layer (22) has ceramic layer (22), unloading piece (23) set up the top front end at casting package (21).

2. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 1, which is characterized in that: the blanking block (23) comprises an empty groove (231), a trigger block (232), a reset spring (233), a lower top block (234), a suck-back device (235) and a material guide device (236), the empty groove (213) is arranged at the inner rear end of the blanking block (23), the trigger block (232) is clamped above the empty groove (231), the reset spring (233) is arranged at the bottom end of the trigger block (232), the lower top block (234) is embedded at the bottom side end of the trigger block (232), the suck-back device (235) is located at the inner front end of the blanking block (23), and the material guide device (236) is embedded at the tail end of the blanking block (23).

3. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 2, characterized in that: the suck-back device (235) comprises a suction groove (a1), an extension spring (a2), a suction block (a3) and a steel wire (a4), wherein the suction groove (a1) is arranged at the front end of the lower block (23) and communicated with the empty groove (231), the extension spring (a2) is embedded and fixed at the bottom end of the suction groove (a1), the suction block (a3) is clamped in the suction groove (a1), one end of the steel wire (a4) is embedded and fixed at the bottom end of the suction block (a3), and the other end of the steel wire is connected to the inside of the empty groove (231).

4. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 3, characterized in that: the absorption block (a3) comprises an absorption body (a31), a supporting column (a32), an elastic rod (a33), an attaching plate (a34) and a fixing ring (a35), wherein the supporting column (a32) is embedded in the middle of the bottom of the absorption body (a31), the two elastic rods (a33) are arranged and are respectively installed at two side ends of the supporting column (a32), the attaching plate (a34) is installed at the side end of the absorption block (a3) and is movably matched with the elastic rod (a33), and the fixing ring (a35) is embedded at the bottom end of the absorption block (a 3).

5. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 2, characterized in that: the material guide device (236) comprises three adsorption tanks (b1), a movable tank (b2), a swinging sheet (b3) and a rewinding spring (b4), the adsorption tanks (b1) are transversely arranged on the upper end face of the material guide device (236), the movable tank (b2) is located at the rear end of the material guide device (236), the swinging sheet (b3) is clamped with the movable tank (b2), and the rewinding spring (b4) is mounted at the side end of the swinging sheet (b 3).

6. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 5, characterized in that: the swing piece (b3) comprises a support body (b31), clamping shafts (b32) and guide pieces (b33), wherein the clamping shafts (b32) are arranged at two ends of the side face of the support body (b31), the clamping shafts (b32) are clamped with the movable grooves (b2), six guide pieces (b33) are arranged, and the six guide pieces are transversely arranged at the front end of the support body (b 31).

7. The magnesium alloy casting ladle continuously exchanged conductor ceramics according to claim 6, which is characterized in that: the guide vane (b33) comprises a guide block (c1), material accumulating grooves (c2) and a protruding block (c3), the guide block (c1) is arranged at two ends of the guide vane (b33), the material accumulating grooves (c2) are located at the upper end of the guide vane (b33), and two protruding blocks (c3) are arranged and transversely arranged on the upper end face of the material accumulating grooves (c 2).