CN215139323U - High-efficient degasser of refined cauldron - Google Patents

Abstract

The utility model discloses a high-efficient degasser of refined cauldron, including refined cauldron casing, feed inlet, sampling mechanism, degasification room, support frame and blow off pipe, the refined cauldron casing outside is equipped with control panel, and is equipped with the blast pipe above refined cauldron casing one side, the feed inlet sets up in refined cauldron casing opposite side top, and refined cauldron casing top is equipped with rabbling mechanism, sampling mechanism sets up in refined cauldron casing one side, and refined cauldron casing opposite side is equipped with temperature monitor, the degasification room sets up inside refined cauldron casing, and degasification room bottom both sides are equipped with the shock attenuation bed course, the support frame passes through welding mode and refined cauldron casing fixed connection, and is equipped with anti-skidding callus on the sole bottom the support frame, the blow off pipe sets up in refined cauldron casing bottom, and blow off pipe one side is equipped with the blowoff valve. This high-efficient degasser of refined cauldron is provided with rabbling mechanism and shock attenuation bed course, and the rabbling mechanism can accelerate degasification speed, and the shock attenuation bed course can effectively play the cushioning effect.

Description

High-efficient degasser of refined cauldron

Technical Field

The utility model relates to a refined cauldron technical field specifically is a high-efficient degasser of refined cauldron.

Background

After the emulsion polymerization is completed, the vacuum degassing process for removing the unreacted monomers needs to be completed in the refining kettle. The emulsion industry generally employs two methods independently to eliminate monomers: firstly, introducing steam into a refining kettle jacket for heat preservation, introducing nitrogen into emulsion, carrying unreacted monomers by utilizing the nitrogen, and pumping out the unreacted monomers by a vacuum system; and secondly, directly introducing steam into the emulsion, and carrying unreacted monomers by utilizing the dual functions of steam condensation and evaporation to be extracted by a vacuum system. The two methods have advantages and disadvantages respectively: the nitrogen method has low steam heat energy utilization rate, water in the emulsion is also pumped out in the removing process, so that the emulsion is continuously concentrated, and the removing effect of the process is limited due to the increase of viscosity; the steam method heat energy, moisturizing two unifications, the desorption is effectual, but takes out the condensate steam and need a large amount of water condensation, in case water can not in time take out in the steam in addition, can cause the increase of emulsion water content, the consequence that the solid content is low excessively. The degasification efficiency of the existing refined kettle is lower, the degasification effect of the refined kettle is not good, the working efficiency is lower, thereby leading to the poorer degasification efficiency, the sampling of the existing refined kettle is more difficult, the sampling of the refined kettle in the degasification process easily influences the degasification effect, the sampling is more inconvenient, the time is longer, and the use is not convenient.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient degasser of refined cauldron to the current refined cauldron degasification efficiency who proposes in solving above-mentioned background art is lower, and refined cauldron degasification effect is not good, and the comparatively difficult problem of current refined cauldron sample.

In order to achieve the above object, the utility model provides a following technical scheme: a high-efficiency degassing device of a refining kettle, which comprises a refining kettle shell, a feed inlet, a sampling mechanism, a degassing chamber, a support frame and a drain pipe, a control panel is arranged on the outer side of the refining kettle shell, an exhaust pipe is arranged above one side of the refining kettle shell, meanwhile, the exhaust pipe is provided with a degassing valve, the feed inlet is arranged above the other side of the refining kettle shell, and the top end of the refining kettle shell is provided with a stirring mechanism, the sampling mechanism is arranged at one side of the refining kettle shell, and a temperature display is arranged at the other side of the refining kettle shell, the degassing chamber is arranged in the refining kettle shell, damping cushion layers are arranged at the two sides of the bottom of the degassing chamber, meanwhile, a damping block is arranged in the damping cushion layer, the support frame is fixedly connected with the refining kettle shell in a welding mode, and the bottom of the support frame is provided with an anti-skidding foot pad, the blow-off pipe is arranged at the bottom of the refined kettle shell, and one side of the blow-off pipe is provided with a blow-off valve.

Preferably, rabbling mechanism includes agitator motor, transmission pivot, shaft coupling, (mixing) shaft and stirring vane, agitator motor sets up in refined cauldron casing top, and agitator motor rotates with the transmission pivot to be connected, the (mixing) shaft sets up inside refined cauldron casing, and the (mixing) shaft passes through shaft coupling and transmission pivot and rotates the connection, is equipped with a plurality of stirring vane on the (mixing) shaft simultaneously.

Preferably, sampling mechanism includes sampling tube, material pump, material valve, sealing washer, sampling bottle and visual level gauge, sampling tube one end is connected with refined cauldron shell inner chamber, and the sampling tube other end and material pump fixed connection, and the material pump top is equipped with the material valve of getting simultaneously, the sampling bottle sets up in the material pump below, and the sampling bottle top is equipped with the sealing washer, and the sampling bottle outside is equipped with visual level gauge simultaneously.

Preferably, the stirring motor, the transmission rotating shaft, the stirring shaft and the stirring blades form a rotating mechanism, and the rotating angle range of the rotating mechanism is 0-360 degrees.

Preferably, six stirring blades are arranged and are symmetrically distributed on two sides of the stirring shaft.

Preferably, the number of the shock absorption blocks is six, and the shock absorption blocks are symmetrically distributed on two sides of the shock absorption cushion layer.

Compared with the prior art, the utility model discloses beneficial effect is: the high-efficiency degasser of the refining kettle,

(1) the stirring mechanism drives the stirring shaft and the stirring blades to rotate through the operation of the stirring motor, so that the raw materials are stirred uniformly, bubbles generated in the raw materials are reduced, the mode is simple and convenient to use, the degassing chamber is arranged in the refining kettle shell, an exhaust pipe is arranged on one side of the refining kettle shell, a degassing valve is arranged on the exhaust pipe, the degassing chamber is convenient for degassing the raw materials, and internal air is convenient to exhaust through the degassing valve;

(2) be provided with sampling tube and sampling bottle, sampling tube one end is connected with refined cauldron shell inner chamber, and the other end is connected with the material pump, and the material pump top is equipped with the valve of getting, opens the valve of getting, is convenient for collect the raw materials through the material pump to in collecting the sampling bottle with the raw materials, the sampling bottle is surveyed outward and is equipped with visual level gauge, through the visual level gauge be convenient for clearly see the raw materials of collecting, and carry out the inspection, can put into production after the inspection is qualified and use.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

fig. 3 is a schematic structural view of the sampling mechanism of the present invention.

In the figure: 1. the device comprises a refining kettle shell, 2, a control panel, 3, an exhaust pipe, 4, a feed inlet, 5, a stirring mechanism, 501, a stirring motor, 502, a transmission rotating shaft, 503, a coupling, 504, a stirring shaft, 505, a stirring blade, 6, a degassing valve, 7, a sampling mechanism, 701, a sampling pipe, 702, a material pump, 703, a material taking valve, 704, a sealing ring, 705, a sampling bottle, 706, a visual liquid level meter, 8, a temperature display, 9, a degassing chamber, 10, a damping cushion layer, 11, a damping block, 12, a support frame, 13, an anti-skid foot pad, 14, a sewage discharge pipe, 15 and a sewage discharge valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a high efficiency degasser for refining kettle, as shown in fig. 1 and fig. 3, a control panel 2 is disposed outside a shell 1 of the refining kettle, an exhaust pipe 3 is disposed above one side of the shell 1 of the refining kettle, an air-releasing valve 6 is disposed on the exhaust pipe 3, a feed inlet 4 is disposed above the other side of the shell 1 of the refining kettle, a stirring mechanism 5 is disposed on the top end of the shell 1 of the refining kettle, a stirring motor 501 is disposed above the shell 1 of the refining kettle, the stirring motor 501 is rotatably connected to a transmission shaft 502, a stirring shaft 504 is disposed inside the shell 1 of the refining kettle, the stirring shaft 504 is rotatably connected to the transmission shaft 502 through a coupling 503, a plurality of stirring blades 505 are disposed on the stirring shaft 504, the stirring motor 501 drives the stirring blades 505 to rotate, so as to uniformly stir the raw material inside the shell 1 of the refining kettle, thereby effectively reducing bubbles generated in the raw material, the raw materials are conveniently degassed, the stirring motor 501, the transmission rotating shaft 502, the stirring shaft 504 and the stirring blades 505 form a rotating mechanism, the rotating angle range of the rotating mechanism is 0-360 degrees, the stirring motor 501 works to drive the transmission rotating shaft 502, the stirring shaft 504 and the stirring blades 505 rotate, the transmission rotating shaft 502 is connected with the stirring shaft 504 through the coupling 503, the mode is simple and convenient to install and use, the stirring blades 505 are six, the stirring blades 505 are symmetrically distributed on two sides of the stirring shaft 504, the stirring effect of the six stirring blades 505 is good, the generation of bubbles in the raw materials is effectively reduced, the mode is simple, and the refined kettle is convenient to degas and use.

As shown in FIG. 3, a sampling mechanism 7 is disposed on one side of a refining kettle housing 1, and a temperature display 8 is disposed on the other side of the refining kettle housing 1, one end of a sampling tube 701 is connected to the inner cavity of the refining kettle housing 1, and the other end of the sampling tube 701 is fixedly connected to a material pump 702, while a material taking valve 703 is disposed above the material pump 702, a sampling bottle 705 is disposed below the material pump 702, and a sealing ring 704 is disposed above the sampling bottle 705, while a visible liquid level meter 706 is disposed outside the sampling bottle 705, the material taking valve 703 is opened, so that the material can be conveniently collected by the material pump 702 and the sampling tube 701, and the material is stored in the sampling bottle 705, the sealing ring 704 is disposed above the sampling bottle 705, the sealing ring 704 has a good sealing effect, a degassing chamber 9 is disposed inside the refining kettle housing 1, and damping cushions 10 are disposed on both sides of the bottom of the degassing chamber 9, damping cushions 11 are disposed inside the damping cushions 10, six damping blocks 11 are disposed inside the damping cushions 11, and the damping cushions 11 are symmetrically disposed on both sides of the damping cushions 10, shock attenuation bed course 10 sets up in 1 bottom of refined cauldron casing, shock attenuation bed course 10 effectively slows down the shock that refined cauldron during operation produced, shock attenuation bed course 10 cooperation snubber block 11 uses, the shock attenuation effect is better, convenient to use, support frame 12 is through welding mode and refined cauldron casing 1 fixed connection, and support frame 12 bottom is equipped with anti-skidding callus on the sole 13, blow off pipe 14 sets up in 1 bottom of refined cauldron casing, and 14 one side of blow off pipe are equipped with blowoff valve 15.

The working principle is as follows: when the high-efficiency degassing device of the refining kettle is used, firstly, the high-efficiency degassing device of the refining kettle is moved to a use place, raw materials flow into a degassing chamber 9 in a shell 1 of the refining kettle through a feed inlet 4, a power supply is switched on, a stirring motor 501 is controlled to work through a control panel 2, a degassing valve 6 is opened, the degassing chamber 9 is in a vacuum state at the moment, the stirring motor 501 works to drive a transmission rotating shaft 502, a stirring shaft 504 and six stirring blades 505 to rotate, the six stirring blades 505 have better stirring effect and are convenient to stir the raw materials, the generation of bubbles in the raw materials is reduced, the mode is simpler and more convenient for the high-efficiency degassing of the raw materials, the stirred waste residues are deposited at the bottom of the shell 1 of the refining kettle, a drain valve 15 is opened and is convenient to discharge the waste residues through a drain pipe 14, a damping cushion layer 10 is arranged at the bottom of the shell 1 of the refining kettle, the damping cushion layer 10 is matched with a damping block 11 and has better damping effect, effectively slow down the vibration generated when the refining kettle works, the mode is simple and convenient for degassing use, the bottom of the support frame 12 is provided with the anti-skidding foot pad 13, the anti-skidding foot pad 13 effectively prevents the refining kettle shell 1 from moving when degassing is carried out, the material taking valve 703 is opened when sampling, the raw material is collected and stored in a sampling bottle 705 through a material pump 702 and a sampling pipe 701, a sealing ring 704 is arranged above the sampling bottle 705, the sealing effect of the sealing ring 704 is better, the raw materials can be conveniently and reasonably sampled by the visual liquid level meter 706, the sampling is finished, the raw materials are inspected, and the raw materials can be put into production for use after being inspected to be qualified, the method is simple, saves sampling time, greatly improves working efficiency, is convenient to use, finishes inspection, cuts off a power supply, removes the high-efficiency degasser of the refining kettle from a use place, and finishes the whole work, and those not described in detail in this specification are well within the skill of those in the art.

The terms "central," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for ease of description, but are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the scope of the invention.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a high-efficient degasser of refined cauldron, includes refined cauldron casing (1), feed inlet (4), sampling mechanism (7), degasification room (9), support frame (12) and blow off pipe (14), its characterized in that: the outer side of the refined kettle shell (1) is provided with a control panel (2), an exhaust pipe (3) is arranged above one side of the refined kettle shell (1), a degassing valve (6) is arranged on the exhaust pipe (3), the feed inlet (4) is arranged above the other side of the refined kettle shell (1), a stirring mechanism (5) is arranged at the top end of the refined kettle shell (1), a sampling mechanism (7) is arranged on one side of the refined kettle shell (1), a temperature display (8) is arranged on the other side of the refined kettle shell (1), a degassing chamber (9) is arranged inside the refined kettle shell (1), damping cushions (10) are arranged on two sides of the bottom of the degassing chamber (9), damping blocks (11) are arranged inside the damping cushions (10), the support frame (12) is fixedly connected with the refined kettle shell (1) in a welding mode, and an anti-skid foot pad (13) is arranged at the bottom of the support frame (12), the blow-off pipe (14) is arranged at the bottom of the refining kettle shell (1), and a blow-off valve (15) is arranged on one side of the blow-off pipe (14).

2. The high-efficiency degassing device for the refining kettle according to claim 1, which is characterized in that: rabbling mechanism (5) are including agitator motor (501), transmission pivot (502), coupling (503), (mixing) shaft (504) and stirring vane (505), agitator motor (501) set up in refined cauldron casing (1) top, and agitator motor (501) rotate with transmission pivot (502) and be connected, stirring shaft (504) set up inside refined cauldron casing (1), and stirring shaft (504) rotate through coupling (503) and transmission pivot (502) and be connected, are equipped with a plurality of stirring vane (505) on stirring shaft (504) simultaneously.

3. The high-efficiency degassing device for the refining kettle according to claim 1, which is characterized in that: sampling mechanism (7) are including sampling tube (701), material pump (702), sampling valve (703), sealing washer (704), sampling bottle (705) and visual level gauge (706), sampling tube (701) one end is connected with refined cauldron casing (1) inner chamber, and sampling tube (701) other end and material pump (702) fixed connection, and material pump (702) top is equipped with sampling valve (703) simultaneously, sampling bottle (705) set up in material pump (702) below, and sampling bottle (705) top is equipped with sealing washer (704), and sampling bottle (705) outside is equipped with visual level gauge (706) simultaneously.

4. The high-efficiency degassing device for the refining kettle according to claim 2, which is characterized in that: the stirring motor (501), the transmission rotating shaft (502), the stirring shaft (504) and the stirring blades (505) form a rotating mechanism, and the rotating angle range of the rotating mechanism is 0-360 degrees.

5. The high-efficiency degassing device for the refining kettle according to claim 2, which is characterized in that: six stirring blades (505) are arranged, and the stirring blades (505) are symmetrically distributed on two sides of the stirring shaft (504).

6. The high-efficiency degassing device for the refining kettle according to claim 1, which is characterized in that: the shock absorption blocks (11) are six, and the shock absorption blocks (11) are symmetrically distributed on two sides of the shock absorption cushion layer (10).

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