CN220665408U - Crystallization barrel stripping device of magnesium ingot smelting reduction furnace - Google Patents

Abstract

The utility model relates to the technical field of magnesium ingot smelting, in particular to a device for pushing out a crystallization barrel of a magnesium ingot smelting reduction furnace. The utility model discloses a device for pushing out a crystallization barrel of a magnesium ingot smelting reduction furnace, which comprises the following components: the device comprises a base, a first hydraulic cylinder, a second hydraulic cylinder, an inner support assembly and a hooking assembly. According to the utility model, the reason that the existing crystallization barrel is easy to unhook is considered, the installation rod with the inner supporting component is additionally arranged on the hydraulic rod II driven by the hydraulic cylinder II, the extension of the hydraulic rod II is utilized to enable the other end of the inner ejector rod to extend into the small opening end of the target crystallization barrel, and then the small opening end is jacked up through the deflection generated by the extension of the controllable telescopic piece, so that the crystallization barrel is righted, and the hook is reliably hooked with the flange on the outer top of the small opening end after the small opening end is jacked up, so that the target crystallization barrel is jacked up along with the shortening of the hydraulic rod II, the whole operation process is simple and rapid, and the success rate of the crystallization barrel is greatly improved.

Description

Crystallization barrel stripping device of magnesium ingot smelting reduction furnace

Technical Field

The utility model relates to the technical field of magnesium ingot smelting, in particular to a device for pushing out a crystallization barrel of a magnesium ingot smelting reduction furnace.

Background

The magnesium vapor is generally crystallized in the crystallization barrel, and is influenced by some factors in actual production, so that a certain proportion of the magnesium vapor can be crystallized outside the crystallization barrel, or the crystallized magnesium grows out of the crystallization barrel, and the crystallization barrel is inconvenient to take out.

The crystallization barrel used in magnesium ingot smelting is a conical barrel with one large end and the other small end. The large opening end of the crystallization barrel extends into the horizontal reduction tank, and the small opening end is close to the outlet of the horizontal reduction tank. Generally, a circle of flange is processed on the outer edge of the small opening end, and a hole for hooking and hanging by a hooking tool is processed on the flange.

However, in the process of actually taking out the crystallization barrel, the inventor finds that the hooking tool is often unhooked from the outer edge of the small opening end when hooking, so that the crystallization barrel cannot be smoothly taken out. The inventor finds through analysis that because the hole at the outer edge is easily covered by the crystal in the step-1, the hooking tool cannot hook the hole; 2, in order to ensure that the crystallization barrel is smoothly filled into the horizontal reduction tank, the outer diameter of the large opening end of the crystallization barrel is smaller than the inner diameter of the horizontal reduction tank, so that the crystallization barrel is not actually horizontally placed in the horizontal reduction tank as shown in fig. 1, but is obliquely arranged with the small opening end hanging down as shown in fig. 2, the bottom of the small opening end is inconvenient to hook, and the top of the crystallization barrel is inclined towards the outlet of the horizontal reduction tank, so that the unhooking probability is increased.

Disclosure of Invention

The utility model provides a device for pulling out a crystallization barrel of a magnesium ingot smelting reduction furnace, which aims to solve the problem that the existing crystallization barrel is pulled out easily to be unhooked by using a hooking tool.

The utility model is realized by adopting the following technical scheme:

the utility model discloses a device for pushing out a crystallization barrel of a magnesium ingot smelting reduction furnace, which comprises the following components: the device comprises a base, a first hydraulic cylinder, a second hydraulic cylinder, an inner support assembly and a hooking assembly.

The first hydraulic cylinder is longitudinally arranged on the base. The first hydraulic rod of the first hydraulic cylinder extends upwards. The second hydraulic cylinder is transversely arranged and connected with the first hydraulic rod. The hydraulic rod of the second hydraulic cylinder extends out towards one side and is connected with a mounting rod. The internal stay subassembly sets up in the installation pole below for jack-up little mouth end from the little mouth end inboard of target crystallization bucket. The inner support assembly comprises a first hinge seat, a controllable telescopic piece, a second hinge seat and an inner ejector rod. The first hinge seat and the second hinge seat are arranged at intervals and are both connected to the bottom surface of the mounting rod. The second hinge seat is farther from the second hydraulic rod than the first hinge seat. The inner ejector rod is an L-shaped bending rod, and the bending end of the inner ejector rod is hinged with the second hinging seat. One end of the controllable expansion piece is hinged with the first hinging seat, and the other end is hinged with one end of the inner ejector rod. The other end of the inner ejector rod stretches into the small opening end of the target crystallization barrel along with the extension of the second hydraulic rod, and deflects along with the extension of the controllable telescopic piece to jack up the small opening end. The hooking component is arranged above the mounting rod. The hooking component comprises a hanging rod and a hook. One end of the hanging rod is connected with the mounting rod. The hook is arranged at the other end of the hanging rod and faces downwards. The hook is hooked with a flange on the outer top of the small opening end after the small opening end is jacked up, and the target crystallization barrel is pulled out along with shortening of the second hydraulic rod.

According to the utility model, the reason that the crystallization barrel is easy to unhook is considered in the prior art, the installation rod with the inner supporting component is additionally arranged on the hydraulic rod II driven by the hydraulic cylinder II, the extension of the hydraulic rod II is utilized to enable the other end of the inner ejector rod to extend into the small opening end of the target crystallization barrel, and then the small opening end is jacked up through the deflection generated by the extension of the controllable telescopic piece, so that the crystallization barrel is righted, and the small opening end is reliably hooked with the flange on the outer top of the small opening end after being jacked up, so that the target crystallization barrel is jacked up along with the shortening of the hydraulic rod II, the whole operation process is simple and rapid, the success rate of the crystallization barrel is greatly improved, and the problem that the crystallization barrel is easy to unhook by the existing hooking tool is solved.

As still further aspects of the utility model: the base is also provided with a longitudinal sliding rail; the outer wall of the hydraulic cylinder is provided with a roller, and the roller is in rolling connection with the sliding rail.

As still further aspects of the utility model: the sliding rails are arranged at intervals, and the rollers are also arranged at intervals and positioned between the two sliding rails.

As still further aspects of the utility model: a moving wheel is arranged below the base and used for driving the whole device to move.

As still further aspects of the utility model: the base is provided with an operation chamber for controlling the work of each component.

As still further aspects of the utility model: the hanging rod is obliquely arranged, and one end of the connecting hook is higher than one end of the connecting installation rod.

As still further aspects of the utility model: the installation rod and the second hydraulic rod are coaxially arranged.

As still further aspects of the utility model: the hook is provided with teeth.

As still further aspects of the utility model: the other end of the inner ejector rod is Y-shaped in a forked way.

As still further aspects of the utility model: the controllable telescopic piece is an electric push rod.

The utility model has the following beneficial effects:

according to the utility model, the reason that the existing crystallization barrel is easy to unhook is considered, the installation rod with the inner supporting component is additionally arranged on the hydraulic rod II driven by the hydraulic cylinder II, the extension of the hydraulic rod II is utilized to enable the other end of the inner ejector rod to extend into the small opening end of the target crystallization barrel, and then the small opening end is jacked up through the deflection generated by the extension of the controllable telescopic piece, so that the crystallization barrel is righted, and the hook is reliably hooked with the flange on the outer top of the small opening end after the small opening end is jacked up, so that the target crystallization barrel is jacked up along with the shortening of the hydraulic rod II, the whole operation process is simple and rapid, and the success rate of the crystallization barrel is greatly improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a view showing the horizontal placement of a crystallization barrel in an ideal state as mentioned in the background art;

FIG. 2 is a view showing an inclined arrangement of a crystallization barrel in an actual state as mentioned in the background art;

FIG. 3 is a diagram showing the structure of the crystallization barrel pulling device of the magnesium ingot smelting reduction furnace before the crystallization barrel is adjusted;

FIG. 4 is a structural diagram of the crystallization barrel pulling device of the magnesium ingot smelting reduction furnace after the crystallization barrel is adjusted;

fig. 5 is a structural view of the inner carrier rod of fig. 3.

In the drawings, the list of components represented by the various numbers is as follows:

1. a horizontal reduction tank;

201. a target crystallization barrel, 202, flange;

3. an operation chamber;

4. a base;

501. hydraulic cylinder one, 502, hydraulic rod one;

6. a slide rail;

7. a connecting rod;

801. a second hydraulic cylinder 802, a second hydraulic rod 803, a roller 804 and a mounting rod;

901. hinge seat one, 902, electric putter, 903, hinge seat two, 904, inner ejector pin, 905, peg, 906, couple.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 3, a structural diagram of a crystallization barrel pulling device of a magnesium ingot smelting reduction furnace is provided. The crystallization barrel at this time is like the one mentioned in the background art, the small opening end hangs down and the whole body tilts.

The utility model provides a magnesium ingot smelting reduction furnace crystallization barrel raking out device includes: base 4, pneumatic cylinder one 501, pneumatic cylinder two 801, internal stay subassembly and collude and get the subassembly.

The base 4 serves as a support for the whole device. Considering that the horizontal reduction tanks 1 are distributed in a honeycomb mode, upper moving wheels can be arranged below the base 4 and used for driving the whole device to move so as to realize displacement. Thus, the base 4 can also be provided with an operating room 3 for controlling the operation of the components. Of course, the base 4 may be fixed to one side of the conventional rail type screw slag-off machine, integrally connected to the rail type screw slag-off machine, and moved together with the rail type screw slag-off machine, and controlled by an operator at the rail type screw slag-off machine.

The first hydraulic cylinder 501 is longitudinally arranged on the base 4. The first hydraulic rod 502 of the first hydraulic cylinder 501 protrudes upward. The first hydraulic cylinder 501 can control the first hydraulic rod 502 to move up and down.

The second hydraulic cylinder 801 is transversely arranged and connected with the first hydraulic rod 502. A second hydraulic rod 802 of the second hydraulic cylinder 801 extends to one side and is connected to a mounting rod 804. The second hydraulic cylinder 801, the second hydraulic rod 802 and the mounting rod 804 can synchronously lift along with the expansion and contraction of the first hydraulic rod 502. Generally, the mounting rod 804 is coaxially arranged with the second hydraulic rod 802, so that the subsequent control of the internal stay assembly and the hooking assembly is facilitated.

In addition, in order to improve the stability of the components such as the second hydraulic cylinder 801, a longitudinal sliding rail 6 may be further arranged on the base 4; the outer wall of the second hydraulic cylinder 801 is provided with a roller 803, and the roller 803 is in rolling connection with the sliding rail 6, so that lifting of the second hydraulic cylinder 801 is guided by the sliding rail 6 and the roller 803. Of course, the number of the slide rails 6 may be one or two. If two slide rails 6 are provided, two rollers 803 are also provided and located between the two slide rails 6, and here, the rolling direction of the rollers 803 and the lifting direction of the second hydraulic cylinder 801 are further limited by the slide rails 6. In addition, the two slide rails 6 can be connected into a whole through a connecting rod 7.

An inner support assembly is provided below the mounting bar 804 for jacking up the small mouth end from the inside of the small mouth end of the target crystallization barrel 201. The inner support assembly comprises a first hinge seat 901, a controllable telescopic piece, a second hinge seat 903 and an inner ejector rod 904. The first hinge seat 901 and the second hinge seat 903 are arranged at intervals and are connected to the bottom surface of the mounting rod 804. Hinge seat two 903 is farther from hydraulic stem two 802 than hinge seat one 901. The inner push rod 904 is an L-shaped bending rod, and the bending end of the inner push rod is hinged with the second hinging seat 903. One end of the controllable expansion piece is hinged with the first hinging seat 901, and the other end is hinged with one end of the inner ejector rod 904. The telescoping of the controllable telescoping member can act on one end of the inner push rod 904, and deflect the inner push rod 904 around the hinge seat one 901, so as to adjust the other end of the inner push rod 904 to tilt or fall back. Generally, the controllable telescopic member may be a commercially available member such as an electric push rod 902, an electric hydraulic rod, or the like.

The hooking assembly is disposed above the mounting bar 804. The hooking assembly includes a hanger bar 905, a hook 906. One end of a hanging rod 905 is connected to the mounting rod 804. The hook 906 is provided at the other end of the hanging bar 905 and faces downward. For the hooking effect of the hook 906, teeth may be machined on the hook 906 to improve the hooking effect with the flange 202.

Referring to fig. 3, the whole device moves to the front of the horizontal reduction tank 1 where the target crystallization barrel 201 is located, and the first hydraulic cylinder 501 is controlled to ascend and descend so that the inner support component is aligned to the target crystallization barrel 201; controlling the second hydraulic rod 802 to extend, and enabling the other end of the inner ejector rod 904 to extend into the small opening end of the target crystallization barrel 201 along with the extension of the second hydraulic rod 802; meanwhile, the hanging rod 905 extends into the horizontal reduction tank 1 along with the extension of the second hydraulic rod 802, as shown in fig. 3, the hanging rod 905 is obliquely arranged, and one end of the connecting hook 906 is higher than one end of the connecting mounting rod 804, so that the hook 906 is higher than the flange 202 and is positioned above the flange 202 when extending into the small opening end; then, the controllable telescopic piece is controlled to stretch, the inner ejector rod 904 deflects and gradually approaches the inner wall of the small opening end and jacks up the small opening end. The small mouth end of the target crystallization barrel 201 is gradually lifted up and gradually contacted with the hooking member.

Referring again to fig. 4, the hooking component is hooked with the flange 202 of the outer top of the small opening end after the small opening end is jacked up, and at this time, the hook 906 hooks or blocks the flange 202 of the outer top of the small opening end, so that the hooking is effectively achieved. And then the second hydraulic rod 802 is controlled to be shortened, so that the target crystallization barrel 201 can be smoothly pulled out of the horizontal reduction tank 1.

Of course, it is also possible to design: the controllable telescopic piece shortens to deflect the inner mandril 904, gradually approaches the inner wall of the small opening end and jacks up the small opening end.

In addition, considering the stability of the target crystallization barrel 201 when being lifted up during use, the other end of the inner push rod 904 may be designed in a Y shape which is branched, as shown in FIG. 5, so that the force application effect is more uniform when contacting the target crystallization barrel 201.

By combining the operation, the device for pulling out the crystallization barrel of the magnesium ingot smelting reduction furnace can reduce unhooking rate and greatly improve success rate of pulling out the crystallization barrel.

It should be noted that, the above electrical components are all connected with the external main controller and 220V mains supply through the transformer, and the main controller can be a conventional known device for controlling a computer, etc., the electrical components provided by the utility model are only used according to the structural characteristics of the product in the technical scheme, the product can be adjusted and modified after purchase, so that the product is more matched with and accords with the technical scheme of the utility model, the product is an optimal application technical scheme of the technical scheme, the model of the product can be replaced and modified according to the required technical parameters, and the main controller is well known to those skilled in the art, so that the corresponding use effect can be obtained by the technical scheme provided by the utility model.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The utility model provides a magnesium ingot smelting reduction furnace crystallization bucket raking out device which characterized in that includes:

a base;

the first hydraulic cylinder is longitudinally arranged on the base; the hydraulic rod I of the hydraulic cylinder I extends upwards;

the hydraulic cylinder II is transversely arranged and connected with the hydraulic rod I; the hydraulic rod of the second hydraulic cylinder extends out from one side of the second hydraulic cylinder and is connected with a mounting rod;

an inner support assembly arranged below the mounting rod and used for jacking up the small opening end from the inner side of the small opening end of the target crystallization barrel; the inner support assembly comprises a first hinging seat, a controllable telescopic piece, a second hinging seat and an inner ejector rod; the first hinge seat and the second hinge seat are arranged at intervals and are connected to the bottom surface of the mounting rod; the second hinge seat is farther from the second hydraulic rod than the first hinge seat; the inner ejector rod is an L-shaped bending rod, and the bending end of the inner ejector rod is hinged with the second hinging seat; one end of the controllable telescopic piece is hinged with the first hinging seat, and the other end of the controllable telescopic piece is hinged with one end of the inner ejector rod; the other end of the inner ejector rod stretches into the small opening end of the target crystallization barrel along with the extension of the second hydraulic rod, and the small opening end is jacked up along with the deflection generated by the extension of the controllable telescopic piece;

and

The hooking component is arranged above the mounting rod; the hooking component comprises a hanging rod and a hook; one end of the hanging rod is connected with the mounting rod; the hook is arranged at the other end of the hanging rod and faces downwards; the hook is hooked with a flange at the outer top of the small opening end after the small opening end is jacked up, and the target crystallization barrel is pulled out along with shortening of the second hydraulic rod.

2. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the base is also provided with a longitudinal sliding rail; the outer wall of the hydraulic cylinder is provided with rollers, and the rollers are in rolling connection with the sliding rail.

3. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 2, wherein: the two sliding rails are arranged at intervals, and the two rolling wheels are arranged between the two sliding rails.

4. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: and a moving wheel is arranged below the base and used for driving the whole device to move.

5. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the base is provided with an operation chamber for controlling the work of each component.

6. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the hanging rod is obliquely arranged, and one end of the connecting hook is higher than one end of the connecting installation rod.

7. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the mounting rod and the second hydraulic rod are coaxially arranged.

8. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 7, wherein: the hook is provided with teeth.

9. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the other end of the inner ejector rod is Y-shaped in a forked mode.

10. The magnesium ingot smelting reduction furnace crystallization barrel scraping device according to claim 1, wherein: the controllable telescopic piece is an electric push rod.