CN214361613U - Lifting crystallization device - Google Patents

Abstract

The utility model provides a lifting crystallization device, which relates to the technical field of magnesium purification and solves the technical problem that the collection of crystallized magnesium is influenced by the fixed arrangement of a crystallizer of magnesium purification equipment in the prior art, wherein the lifting crystallization device comprises a lifting body and a crystallization disc assembly, the lifting body is connected with a driving device in a transmission way and can be driven by the driving device to lift; the crystallizing disc assembly comprises a crystallizing disc and an isolating ring, the crystallizing disc is connected with the lifting body, the isolating ring is sleeved on the crystallizing disc, and the temperature of the isolating ring is higher than that of the crystallizing disc; the utility model can drive the crystallizing tray component to lift through the lifting body which is connected with the driving device in a transmission way; the magnesium vapor can be crystallized on the crystallizing disc only through the crystallizing disc and the isolating ring, relatively independent crystallized magnesium can be formed, smooth going of lifting action is guaranteed, crystallization is regular, and collection and discharging of magnesium are facilitated.

Description

Lifting crystallization device

Technical Field

The utility model relates to a magnesium purification technical field, concretely relates to lift crystallization device.

Background

The production of high-purity metal magnesium usually comprises placing crude magnesium in a vacuum environment to heat to form steam, and obtaining high-purity magnesium after cooling and crystallizing.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a lifting crystallization device to solve the technical problem that the collection of crystallized magnesium is influenced by the fixed arrangement of a crystallizer of the existing magnesium purification equipment in the prior art; the utility model provides a plurality of technical effects that the preferred technical scheme in a plurality of technical schemes can produce (the crystallization dish is internally provided with an installation cavity used for installing a cooling coil pipe, the cooling coil pipe is uniformly cooled, the cooling coil pipe is connected with a cooling liquid inlet pipe and a cooling liquid outlet pipe and can form a cooling liquid circulation loop, a liquid inlet end and a liquid outlet end of the cooling dish are both arranged at the middle position of the cooling coil pipe, cooling liquid in the cooling coil pipe flows from inside to outside and from outside to inside in a circulation manner, the cooling effect is obvious, a lifting body is arranged as a lifting pipe and can drive the crystallization dish assembly to lift on one hand and be used for accommodating and installing the cooling liquid inlet pipe and the liquid outlet pipe on the other hand, the top end of the cooling liquid inlet pipe is connected with a liquid inlet joint used for installing a liquid inlet pipeline, the top end of the cooling liquid outlet pipe is connected with a liquid outlet joint used for installing a liquid outlet pipeline, the crystallization dish comprises a first dish body and a second dish body, the lifting body and the isolating ring are respectively connected, and an installation chamber for accommodating the cooling coil can be formed; the lifting crystallization device comprises a temperature measuring mechanism for detecting the temperature of the cooling disc; the temperature measuring mechanism comprises a first temperature measuring element and a second temperature measuring element, the first tray body and the second tray body are provided with a first mounting hole and a second mounting hole, the detecting ends of the first temperature measuring element and the second temperature measuring element are respectively inserted into the first mounting hole and the second mounting hole, and temperature detection is accurate; the outer diameter of the isolating ring is matched with the size of a crystallization cavity of the crystallizer, so that the magnesium vapor flowing to the upper side of the crystallization disc is reduced, the collection rate is improved, and the like); see below for details.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model provides a pair of lift crystallization device, including the body and crystallization dish subassembly that go up and down, wherein: the lifting body is in transmission connection with the driving device and can be driven by the driving device to lift; the crystallizing disc assembly comprises a crystallizing disc and an isolating ring, the crystallizing disc is connected with the lifting body, the isolating ring is sleeved on the crystallizing disc, and the temperature of the isolating ring is higher than that of the crystallizing disc.

The lifting crystallization device of the utility model is mainly used for purifying magnesium, but is not limited to magnesium.

Preferably, the crystallization tray is internally provided with a mounting chamber, wherein: a cooling coil is arranged in the mounting cavity; the liquid inlet end of the cooling coil is connected with a cooling liquid inlet pipe; and the liquid outlet end of the cooling coil is connected with a cooling liquid outlet pipe.

Preferably, the liquid inlet end and the liquid outlet end of the cooling coil are both arranged at the middle position of the cooling coil.

Preferably, the lifting body is provided as a riser, the riser being vertically arranged, wherein: the lifting pipe is in transmission connection with the driving device; the bottom end of the lifting pipe is vertically connected with the crystallization disc; the cooling liquid inlet pipe and the cooling liquid outlet pipe are vertically arranged in the lifting pipe.

Preferably, the bottom end of the cooling liquid inlet pipe is connected with the cooling coil pipe; the top end of the cooling liquid inlet pipe penetrates through the lifting pipe and is connected with a liquid inlet joint.

Preferably, the bottom end of the cooling liquid outlet pipe is connected with the cooling coil pipe; the top end of the cooling liquid outlet pipe penetrates through the lifting pipe and is connected with a liquid outlet joint.

Preferably, the crystallization tray comprises a first tray body and a second tray body, wherein: the first tray body is arranged on the second tray body and encloses the mounting chamber; the lifting body is vertically arranged on the first tray body; the isolation ring is sleeved on the second tray body.

Preferably, the lifting crystallization device comprises a temperature measuring mechanism, and the temperature measuring mechanism is connected with the crystallization tray to detect the temperature of the crystallization tray.

Preferably, the temperature measuring mechanism includes a first temperature measuring element and a second temperature measuring element, wherein: a first mounting hole is formed in the wall of the first tray body, and the detection end of the first temperature measurement element is inserted into the first mounting hole; and a second mounting hole is formed in the wall of the second tray body, and the detection end of the second temperature measurement element is inserted into the second mounting hole.

Preferably, the external diameter of the spacer ring is matched with the diameter size of the internal cavity of the crystallizer.

The utility model provides a pair of lift crystallization device has following beneficial effect at least:

the lifting crystallization device comprises a lifting body and a crystallization tray assembly, wherein the crystallization tray assembly is used for crystallization.

The lifting body is connected with the driving device in a transmission way, and can be lifted or lowered under the driving of the driving device.

The crystallizing disc assembly comprises a crystallizing disc and an isolating ring, the crystallizing disc is connected with the lifting body, magnesium vapor can be crystallized on the crystallizing disc, crystallized magnesium is continuously accumulated in the process of producing high-purity metal magnesium, and meanwhile, the crystallizing disc is lifted under the driving of the lifting body, so that the magnesium vapor is kept crystallized in a specified area, and the collection amount of the crystallized magnesium is obviously improved.

The barrier ring cover is established on the crystallization dish, the temperature of barrier ring is higher than the temperature of crystallization dish, and magnesium vapour can't be at the barrier ring crystallization, can crystallize the relatively independent crystal magnesium of formation on making the crystallization dish, not only guarantees going on smoothly of lift action, and the crystallization is comparatively regular moreover, is convenient for the collection and the ejection of compact of magnesium.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic view of the structure of the utility model in use;

fig. 2 and fig. 3 are schematic structural sectional views of the present invention.

Reference numerals

1. A lifting body; 2. a crystallization tray assembly; 21. a crystallization tray; 211. a cooling coil; 212. a coolant inlet pipe; 213. a coolant outlet pipe; 214. a liquid inlet joint; 215. a liquid outlet joint; 216. a first tray body; 2161. a first mounting hole; 217. a second tray body; 2171. a second mounting hole; 22. an isolating ring; 3. a temperature measuring mechanism; 31. a first temperature measuring element; 32. a second temperature measuring element; 4. an internal cavity of the crystallizer; 5. and (3) supporting the ring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

The utility model provides a lift crystallization device, as shown in fig. 1-3, lift crystallization device includes lift body 1 and crystallizing dish subassembly 2, wherein: the upper section of the lifting body 1 is in transmission connection with a driving device and can be driven by the driving device to lift, the driving device adopts the existing driving device and can be set as a pneumatic telescopic lifting device, a hydraulic telescopic lifting device or an electric telescopic lifting device; the crystallizing disc assembly 2 comprises a crystallizing disc 21 and an isolating ring 22, the crystallizing disc 21 is connected with the lifting body 1, the isolating ring 22 is sleeved on the crystallizing disc 21, and the temperature of the isolating ring 22 is higher than that of the crystallizing disc 21.

The crystallizing disc 21 is positioned in the inner cavity 4 of the crystallizer, the lifting body 1 is connected with the crystallizing disc 21, and the upper section of the lifting body extends out of the inner cavity 4 of the crystallizer.

During the use, the magnesium vapour in the internal cavity 4 of crystallizer meets the cold crystallization on the bottom surface of crystallization dish 21, drive arrangement drives lifting body 1 and promotes, and crystallization dish 21 promotes in step, makes the stable crystallization in the appointed region of magnesium vapour, and at this in-process, the temperature of isolating ring 22 is higher than the temperature of crystallization dish 21 to effectively avoid the magnesium vapour to crystallize on isolating ring 22, make and form relatively independent crystal magnesium on the crystallization dish 21, avoid influencing the lift action of crystallization dish 21.

The utility model can drive the crystallizing dish component 2 to lift through the lifting body 1 which is connected with the driving device in a transmission way; the magnesium vapor can be crystallized on the crystallizing disc 21 only through the crystallizing disc 21 and the isolating ring 22, so that relatively independent crystallized magnesium is formed, smooth ascending and descending actions are guaranteed, crystallization is regular, and collection and discharging of magnesium are facilitated.

As an alternative embodiment, as shown in fig. 2 and 3, the crystallization disk 21 is internally provided with a mounting chamber, wherein: a cooling coil 211 is arranged in the installation cavity; the liquid inlet end of the cooling coil 211 is connected with a cooling liquid inlet pipe 212; the liquid outlet end of the cooling coil 211 is connected with a cooling liquid outlet pipe 213.

As an alternative embodiment, the liquid inlet end and the liquid outlet end of the cooling coil 211 are both disposed at the middle position of the cooling coil 211.

As an alternative embodiment, the lifting body 1 is provided as a lifting tube, which is arranged vertically, wherein: the lifting pipe is in transmission connection with the driving device; the bottom end of the lifting pipe is vertically arranged at the middle position of the crystallization tray 21, and the cooling liquid inlet pipe 212 and the cooling liquid outlet pipe 213 are vertically arranged in the lifting pipe.

As an alternative embodiment, the bottom end of the cooling liquid inlet pipe 212 is connected with the liquid inlet end of the cooling coil 211; the top end of the coolant liquid inlet pipe 212 penetrates through the lifting pipe and is connected with a liquid inlet joint 214, and the liquid inlet joint 214 is used for being connected with a coolant liquid inlet pipeline.

In an alternative embodiment, the bottom end of coolant outlet pipe 213 is connected to the outlet end of cooling coil 211; the top end of the cooling liquid outlet pipe 213 penetrates through the lifting pipe and is connected with a liquid outlet joint 215, and the liquid outlet joint 215 is used for being connected with a cooling liquid outlet pipeline.

The cooling liquid enters the cooling coil 211 through the cooling liquid inlet pipe 212 and is discharged through the cooling liquid outlet pipe 213, so that a cooling liquid circulation loop can be formed.

A cooling liquid inlet pipe 212 and a cooling liquid outlet pipe 213, the inlet and outlet of which can be replaced.

As an alternative embodiment, as shown in fig. 3, crystallization tray 21 comprises a first tray body 216 and a second tray body 217, wherein: the first tray body 216 is arranged on the second tray body 217 and encloses the installation chamber, and the installation chamber is matched with the cooling coil 211 in size, so that the cooling surface of the second tray body 217 can be sufficiently cooled; the lifting body 1 is vertically arranged on the first disc body 216; the isolating ring 22 is sleeved on the second disc body 217, the bottom surface of the second disc body 217 is a cooling surface, and the bottom surface of the isolating ring 22 is flush with the cooling surface.

As an alternative embodiment, as shown in FIGS. 1 and 2, the lifting crystallization device comprises a temperature measuring mechanism 3, and the temperature measuring mechanism 3 is connected with the crystallization tray 21 and used for detecting the temperature of the crystallization tray 21.

As an alternative embodiment, the temperature measuring mechanism 3 includes a first temperature measuring element 31 and a second temperature measuring element 32, and the first temperature measuring element 31 and the second temperature measuring element 32 are provided as thermocouple temperature sensors.

A first mounting hole 2161 is formed in the wall of the first tray body 216 along the radius direction of the cross section of the first tray body, and the detection end of the first temperature measurement element 31 is inserted into the first mounting hole 2161.

The wall of the second plate 217 is provided with a second mounting hole 2171 along the radial direction of the cross section thereof, and the detection end of the second temperature measuring element 32 is inserted into the second mounting hole 2171.

As an alternative embodiment, the isolation ring 22 is configured as an edge ring of the crystallization disk 21, and the outer diameter of the isolation ring 22 is matched with the diameter size of the inner cavity 4 of the crystallizer, so that the crystallization efficiency of the crystallization disk 21 is improved without affecting the lifting action.

As an alternative embodiment, as shown in fig. 1, before being put into use (in a test stage), the lifting body 1 is fixedly sleeved with a support ring 5, the support ring 5 is detachably disposed on the mold, the support ring 5 can fix the lifting body 1 on the mold, in the process, the lifting body 1 is fixed and cannot lift, so as to facilitate collection of data parameters, in the use process, the support ring 5 needs to be detached in advance, and the lifting body 1 can lift under the driving of the driving device.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present invention, and all should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. An elevated crystallization device, characterized in that it comprises an elevated body (1) and a crystallization tray assembly (2), wherein:

the lifting body (1) is in transmission connection with a driving device and can be driven by the driving device to lift;

crystallizing dish subassembly (2) includes crystallizing dish (21) and spacer ring (22), crystallizing dish (21) with it links to each other to go up and down body (1), spacer ring (22) cover is established on crystallizing dish (21), the temperature of spacer ring (22) is higher than the temperature of crystallizing dish (21).

2. Lifting crystallization device according to claim 1, characterized in that the crystallization tray (21) is provided with a mounting chamber inside, wherein:

a cooling coil (211) is arranged in the mounting chamber;

the liquid inlet end of the cooling coil (211) is connected with a cooling liquid inlet pipe (212);

and the liquid outlet end of the cooling coil (211) is connected with a cooling liquid outlet pipe (213).

3. The apparatus of claim 2, wherein the inlet end and the outlet end of the cooling coil (211) are disposed at the middle position of the cooling coil (211).

4. The lift crystallization device according to claim 2, characterized in that the lift body (1) is provided as a lift tube, which is vertically arranged, wherein:

the lifting pipe is in transmission connection with the driving device;

the bottom end of the lifting pipe is vertically connected with the crystallization disc (21);

the cooling liquid inlet pipe (212) and the cooling liquid outlet pipe (213) are vertically arranged in the lifting pipe.

5. The lift crystallization device according to claim 4, characterized in that the bottom end of the cooling liquid inlet pipe (212) is connected to the cooling coil (211);

the top end of the cooling liquid inlet pipe (212) penetrates through the lifting pipe and is connected with a liquid inlet joint (214).

6. The lift crystallization device of claim 4, wherein the bottom end of the coolant outlet pipe (213) is connected to the cooling coil (211);

the top end of the cooling liquid outlet pipe (213) penetrates through the lifting pipe and is connected with a liquid outlet joint (215).

7. The lift crystallization device of claim 2, wherein the crystallization tray (21) comprises a first tray body (216) and a second tray body (217), wherein:

the first tray body (216) is arranged on the second tray body (217) and encloses the mounting chamber;

the lifting body (1) is vertically arranged on the first disc body (216);

the isolating ring (22) is sleeved on the second disc body (217).

8. The lifting crystallizer as claimed in claim 7, characterized in that the lifting crystallizer comprises a temperature measuring mechanism (3), and the temperature measuring mechanism (3) is connected with the crystallizing tray (21) to detect the temperature of the crystallizing tray (21).

9. The lift crystallization device according to claim 8, characterized in that the temperature measuring means (3) comprises a first temperature measuring element (31) and a second temperature measuring element (32), wherein:

a first mounting hole (2161) is formed in the wall of the first tray body (216), and the detection end of the first temperature measurement element (31) is inserted into the first mounting hole (2161);

a second mounting hole (2171) is formed in the wall of the second tray body (217), and the detection end of the second temperature measuring element (32) is inserted into the second mounting hole (2171).

10. Lifting crystallization device according to claim 1, characterized in that the outside diameter of the spacer ring (22) is dimensioned to the diameter of the crystallizer internal cavity (4).

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