CN113209660A - Antifreezing solution and processing technology thereof - Google Patents

Abstract

The invention belongs to the technical field of antifreeze fluid processing, and particularly relates to an antifreeze fluid and a processing technology thereof; the invention provides an antifreeze fluid processing technology, which comprises the following steps: s1: pouring an antifreeze solution material into a storage part in a crystallization device, and then placing the storage part in a low-temperature environment; s2: stirring in the storage part by using a mixing part in the crystallization device to uniformly mix all components of the antifreeze solution, so as to avoid low-temperature crystallization of a single material; s3: the mixing part salvages the crystallized macromolecular materials in the stirring process in the storage part, and finally, the optimization scheme of the anti-freezing solution can be analyzed according to the detected types of the salvaged materials; the crystallization device comprises a storage part for storing various raw materials of the antifreeze and a mixing part capable of stirring in the storage part, wherein the mixing part is used for fishing large-particle crystals in the antifreeze by changing the aperture of the material to enter and exit; the technology can realize the function of continuously optimizing the formula of the antifreeze solution.

Description

Antifreezing solution and processing technology thereof

Technical Field

The invention belongs to the technical field of antifreeze fluid processing, and particularly relates to antifreeze fluid and a processing technology thereof.

Background

For example, application number 201220445915. vacuum irrigation device for antifreeze solution in cavity of X submersible motor, the utility model discloses a vacuum filling device for antifreeze solution in a cavity of a submersible motor, which comprises a vacuum pump, an extraction pipeline, an antifreeze solution box, an antifreeze solution suction pipe and a PLC, wherein the vacuum pump is communicated with the cavity of the submersible motor through the extraction pipeline, the cavity of the submersible motor is communicated with the antifreeze solution box through the antifreeze solution suction pipe, antifreeze solution is placed in the antifreeze solution box, a vacuum pressure sensor is arranged on the extraction pipeline, a preset value is set on the vacuum pressure sensor, a water level sensor is arranged in the cavity and can sense the water level of the antifreeze solution in the cavity, the water level sensor is connected with the PLC, the PLC is connected with the vacuum pump, the utility model improves the efficiency and quality of the antifreeze fluid poured into the cavity of the submersible motor through the cooperation of the vacuum pressure sensor, the water level sensor, the vacuum pump and the PLC; but the utility model does not have the function of optimizing the formula of the antifreeze solution.

Disclosure of Invention

In view of this, the technical problem to be solved by the present invention is to provide an antifreeze processing technology, which can realize the function of continuously optimizing the antifreeze formula.

The invention provides an antifreeze fluid processing technology, which comprises the following steps:

s1: pouring an antifreeze solution material into a storage part in a crystallization device, and then placing the storage part in a low-temperature environment;

s2: stirring in the storage part by using a mixing part in the crystallization device to uniformly mix all components of the antifreeze solution, so as to avoid low-temperature crystallization of a single material;

s3: the mixing part is used for fishing the crystallized macromolecular materials in the stirring process in the storage part, and finally, the optimization scheme of the anti-freezing solution can be analyzed according to the types of the detected and fished materials.

The crystallization device comprises a storage part for storing each raw material of the antifreeze solution and a mixing part capable of stirring in the storage part, wherein the mixing part is used for fishing large-particle crystals in the antifreeze solution by changing the aperture of the material to enter and exit.

The antifreeze material is poured into the storage part, and the mixing part is moved in the storage part, so that the antifreeze material in the storage part can be mixed by the mixing part, and the mixing effect of each component of the antifreeze is improved.

The storage part comprises a mixing tank, two liquid conveying pipes and a sliding groove plate, the two liquid conveying pipes are arranged on the mixing tank, the liquid conveying pipes are communicated with the mixing tank, plugs are arranged on the liquid conveying pipes, the sliding groove plate is arranged on the side part of the mixing tank, and the mixing part is connected in the sliding groove plate.

Two liquid conveying pipes are symmetrically arranged on the mixing tank, one liquid conveying pipe is used for filling liquid, and the other liquid conveying pipe is used for discharging liquid. The liquid in the mixing tank is conveyed through the two liquid conveying pipes, so that the device can be continuously used, and the processing efficiency of the device is improved.

The mixing portion includes stirring board, control lever and separation blade, installs the control lever on the stirring board, installs the separation blade on the control lever, is equipped with on the separation blade and keeps off along, and separation blade and chute board laminating keep off along the cover on the chute board, and the stirring board can laminate with the inboard of blending tank.

The stirring plate can be slid in the mixing tank by a control rod. The stirring plate can be rotated in the mixing tank by a control lever.

The antifreeze fluid comprises the following components: according to the mass parts, 30 parts of ethylene glycol, 2 parts of triethanolamine, 3 parts of hydrolyzed maleic anhydride, 2 parts of EDTA and 100 parts of water are taken.

The crystallization device used in the antifreeze fluid processing technology has the beneficial effects that:

by fishing the crystallized macromolecular material and adjusting the proportion of the crystallized material to the antifreeze solution formula material, the technology realizes the function of continuously optimizing the antifreeze solution formula.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic structural diagram of a first embodiment of a storage unit according to the present invention;

FIG. 2 is a schematic structural view of a stirring plate provided by the present invention;

FIG. 3 is a schematic view of the structure of a mounting window provided by the present invention;

fig. 4 is a schematic structural view of a second embodiment of the storage unit according to the present invention;

FIG. 5 is a schematic structural view of a splice provided by the present invention;

FIG. 6 is a schematic structural view of a sight tube according to the present invention;

FIG. 7 is a schematic structural view of a liquid filling tube according to the present invention;

FIG. 8 is a schematic structural view of a drum provided by the present invention;

FIG. 9 is a schematic view of a gear according to the present invention;

FIG. 10 is a schematic structural view of a cannula provided in accordance with the present invention;

fig. 11 is a schematic structural view of the elastic sampling tube provided in the present invention.

In the figure:

a mixing tank 101;

an infusion tube 102;

a chute plate 103;

a splice tab 104;

a perforation 105;

a retaining member 106;

an observation tube 107;

a breather pipe 108;

a stirring plate 201;

a control lever 202;

a stopper 203;

a stop edge 204;

a mounting window 205;

a flow port 206;

a resilient flap 207;

a temporary storage funnel 301;

a liquid filling pipe 302;

a rotating frame 303;

a rotating drum 304;

a rotating plate 305;

a stirring bar 306;

a gear 401;

a rack 402;

an insertion tube 501;

a partition 502;

an inner tube 503;

an elastic sampling tube 601;

controlling the arm 602.

Detailed Description

The antifreeze fluid processing technology provided by the invention is described in detail with reference to the accompanying drawings in the embodiment of the invention.

As a further improved technical solution of the present invention, refer to fig. 1:

the mixing part can be designed to stir in the storage part, so that the effect of discharging bubbles in the anti-freezing solution when the anti-freezing solution material is poured into the storage part can be improved, and the damage of gas in the anti-freezing solution to the sealing quality of the anti-freezing solution is reduced when the storage part is placed in a low-temperature environment for storage;

furthermore, the mixing part can be designed to stir in the storage part, so that materials which are easy to precipitate in the antifreeze can be mixed with other materials again, the quality of the prepared antifreeze is further improved, and the occurrence of antifreeze agglomeration caused by precipitation can be reduced;

after the storage part is placed in a low-temperature environment, the environment temperature is gradually reduced, and the effect of detecting the using capacity of the anti-freezing solution in the storage part can be realized;

after the storage part is placed in a low-temperature environment, the environment temperature is gradually reduced, and at the moment, the antifreezing solution is gradually close to the use limit, so that the material in the storage part is gradually crystallized;

the mixing part salvages large-particle crystals in the antifreeze liquid by changing the aperture of the inlet and outlet of the material, and the design can salvage the crystals generated in the antifreeze liquid material due to low temperature in the antifreeze liquid material;

by fishing the crystallized macromolecular material and adjusting the proportion of the crystallized material to the antifreeze solution formula material, the technology realizes the function of continuously optimizing the antifreeze solution formula.

In order to prevent the infusion tube 102 for liquid drainage from being blocked due to long-term use, the two infusion tubes 102 can be used in an inverted manner after a period of time;

by providing the chute plate 103 in the mixing tank 101, the mixing section is slid in the chute plate 103, whereby the antifreeze material in the storage section is agitated by the mixing section.

As a further improved technical solution of the present invention, refer to fig. 1-2:

the stirring plate 201 is controlled to slide in the mixing tank 101 and rotate at the same time, so that the mixing effect of the antifreeze liquid material can be improved;

since the agitating plate 201 is flat and the agitating plate 201 can be attached to the inside of the mixing tank 101, when the control rod 202 is moved in the chute plate 103, the agitating plate 201 scrapes off the antifreeze solid-liquid mixture adhered to the inner wall of the mixing tank 101;

the baffle plate 203 is attached to the sliding chute plate 103, and the baffle edge 204 is sleeved on the sliding chute plate 103, so that the sealing effect can be realized, and the anti-freezing solution material in the mixing tank 101 is prevented from overflowing and scattering while the stirring plate 201 is stirred in the mixing tank 101;

the thickness of the stirring plate 201 is wider than the width of the chute plate 103, so that the stirring plate 201 is clamped in the mixing tank 101, and the sealing effect of the device is improved.

As a further improved technical solution of the present invention, refer to fig. 1:

the stirring plate 201 is provided with a plurality of circulation ports 206 which penetrate through two ends of the stirring plate 201.

The design of the circulation ports 206 can drive the antifreeze to flow back and forth from the plurality of circulation ports 206 when the stirring plate 201 rotates by taking the axis of the control rod 202 as an axis, so that the effect of mixing the antifreeze by the device is improved;

further, the design of the flow port 206 facilitates the interception of the crystallized antifreeze material passing through the flow port 206, thereby facilitating the fishing of the crystallized antifreeze material.

As a further improved technical solution of the present invention, refer to fig. 2-3:

the stirring plate 201 is hollow inside, the stirring plate 201 is provided with an installation window 205, the installation window 205 is provided with a permeable membrane, the circulation port 206 is provided with an elastic valve 207 which is contracted inwards, the control rod 202 is hollow inside, the control rod 202 is communicated with the stirring plate 201 inside, and a sampling assembly is arranged in the control rod 202.

The transparent membrane is arranged at the mounting window 205, and each flow port 206 is provided with the elastic flap 207 which contracts inwards, so that the function of intercepting the crystallized antifreeze material which passes through the flow port 206 can be realized, and the antifreeze material can only enter the stirring plate 201 from the elastic flap 207 and cannot be discharged from the elastic flap 207 through the elasticity and the mounting direction of the elastic flap 207 which contracts inwards;

in order to improve the effect of unidirectional flow of the antifreeze solution material, a plurality of elastic petals 207 can be arranged at one flow port 206, and the sealing effect and the unidirectional flow effect between the elastic petals 207 can improve the effect of intercepting the crystallized antifreeze solution material by the device;

after entering the stirring plate 201 from the elastic flap 207, the antifreeze material can be discharged only through the permeable membrane, and the permeable membrane adopts a polymer material semipermeable membrane technology, so that the crystallized antifreeze material can be intercepted, and the non-crystallized antifreeze material can be smoothly discharged;

under the action of the permeable membrane and the elastic flap 207, the stirring plate 201 stirring in the mixing tank 101 can salvage the antifreeze crystallized in the mixing tank 101 when the mixing among various antifreeze composition materials is controlled, and the quality of the antifreeze produced by the device can be improved because the mixing tank 101 is in a low-temperature environment;

furthermore, the antifreeze crystallized in the mixing tank 101 is salvaged, and the ratio of the crystallized material to the antifreeze formula material is adjusted, so that the technology can realize the function of constantly optimizing the antifreeze formula.

As a further improved technical solution of the present invention, refer to fig. 4-5:

mixing tank 101 comprises two half tank pieces concatenation, and equal symmetry installs two concatenation pieces 104 on every half tank piece, is provided with a plurality of perforation 105 on the concatenation piece 104, runs through perforation 105 on two half tank pieces through retaining member 106 and fastens between two half tank pieces.

The design that the two half tank pieces are spliced to form the mixing tank 101 can improve the easy cleaning effect of the mixing tank 101;

the two half tank pieces are disassembled, and the interior of the mixing tank 101 can be cleaned in a direct cleaning mode, so that the maintenance effect of the device is improved;

furthermore, the design of disassembling and cleaning the two half tank pieces can ensure that the device can not pollute each other when processing various anti-freezing solutions.

As a further improved technical solution of the present invention, refer to fig. 6:

an observation pipe 107 is arranged on the mixing tank 101, and two ends of the observation pipe 107 are communicated with the mixing tank 101.

The observation tube 107 is made of a low-temperature-resistant transparent material;

a communicating vessel is formed between the observation pipe 107 and the mixing tank 101, and the liquid level in the mixing tank 101 can be observed through the observation pipe 107, so that the storage amount of the antifreeze liquid material in the mixing tank 101 can be conveniently controlled;

further, the observation pipe 107 is designed to facilitate direct observation of the crystal content in the antifreeze material in the mixing tank 101;

further, when the observation tube 107 observes that the content of crystals of the antifreeze material in the mixing tank 101 is too high, the stirring operation of the stirring plate 201 can be stopped in advance, thereby preventing damage to the permeable membrane and the elastic flap 207.

As a further improved technical solution of the present invention, refer to fig. 7:

the infusion tube 102 at the upper side is communicated with a vent tube 108, a one-way valve is arranged on the vent tube 108, and the infusion tube 102 is provided with a filling assembly.

The design of the vent pipe 108 is convenient for discharging gas in the mixing tank 101 when the anti-freezing liquid material is filled into the mixing tank 101, so that the effect of filling the anti-freezing liquid material is improved;

the one-way valve arranged on the vent pipe 108 plays a role in assisting the one-way circulation of gas;

the design of the filling assembly facilitates filling of the mixing tank 101 with antifreeze material.

As a further improved technical solution of the present invention, refer to fig. 7-8:

the filling subassembly includes temporary storage funnel 301, irritate liquid pipe 302, revolving rack 303, rotary drum 304, commentaries on classics board 305 and stirring strip 306, fixed connection and intercommunication have temporary storage funnel 301 on being located the transfer line 102 of upside, a plurality of irritate liquid pipes 302 of the even fixedly connected with of circumference of temporary storage funnel 301 upper end, fixedly connected with revolving rack 303 on the temporary storage funnel 301, the articulated rotary drum 304 that is connected with on the revolving rack 303, a plurality of commentaries on classics boards 305 of the upper end fixedly connected with of rotary drum 304, the virtual axis of irritate liquid pipe 302 runs through commentaries on classics board 305, a plurality of stirring strips 306 of lower extreme fixedly connected with of rotary drum 304, stirring strip 306 and temporary storage funnel 301's inboard laminating.

Because the virtual axis of the liquid filling pipe 302 penetrates through the rotating plate 305, when antifreeze is filled into the temporary storage funnel 301 from the liquid filling pipe 302, the antifreeze can cause impact force to the rotating plate 305, so that the rotating drum 304 can rotate on the rotating frame 303 by taking the axis of the rotating drum 304 as the axis, and at the moment, the stirring bar 306 can rotate by taking the axis of the rotating drum 304 as the axis, so that the function of stirring various materials is realized, and the mixing effect of the antifreeze is improved.

As a further improved technical solution of the present invention, refer to fig. 9:

the crystallization device further comprises a gear 401 and a rack 402, wherein the gear 401 is installed on the control rod 202, the gear 401 is in transmission connection with the rack 402, and the rack 402 is fixedly connected with the mixing tank 101 through a connecting plate.

The design of the transmission connection between the gear 401 and the rack 402 enables the gear 401 and the rack 402 to move relatively when the control rod 202 slides in the chute plate 103, so that the gear 401 drives the control rod 202 to rotate by taking the axis of the gear 401 as the shaft;

the design that the control rod 202 slides and rotates in the chute plate 103 enables the stirring plate 201 to uniformly stir the antifreeze material in the mixing tank 101, maintains a certain stirring frequency and amplitude, and realizes the function of stable processing of the device.

As a further improved technical solution of the present invention, refer to fig. 10-11:

the sampling assembly comprises an insertion tube 501, a partition plate 502, an inner tube 503, an elastic sampling tube 601 and a control arm 602, two ends of a control rod 202 are open, the insertion tube 501 is slidably connected in the control rod 202, the insertion tube 501 is hollow, the opening at one end and the other end of the insertion tube 501 are closed, the insertion tube 501 is fixedly connected with the inner tube 503 through the partition plate 502, the elastic sampling tube 601 is slidably connected between the insertion tube 501 and the inner tube 503, the control arm 602 is fixedly connected to the elastic sampling tube 601, and the control arm 602 penetrates through the partition plate 502 and the insertion tube 501.

Since the stirring plate 201 is positioned in the mixing tank 101, it is inconvenient to take out the antifreeze crystals fished in the stirring plate 201, and therefore, the insertion tube 501 which can slide in the control rod 202 and the elastic sampling tube 601 which can slide in the insertion tube 501 are provided, so that the antifreeze crystals fished in the stirring plate 201 can be taken out;

the elastic sampling tube 601 has elasticity, and when the end of the elastic sampling tube 601 is pulled out from the end of the insertion tube 501, the opening of the end of the elastic sampling tube 601 can be automatically plugged, so that when the insertion tube 501 and the elastic sampling tube 601 are taken out from the control rod 202 together, direct contact between the antifreeze crystals and the outside can be avoided, the processing precision of the device is improved, and the antifreeze crystals can be conveniently detected;

the position of the flexible sampling tube 601 within the cannula 501 can be controlled by the control arm 602;

the design that the elastic sampling tube 601 is connected between the insertion tube 501 and the inner tube 503 in a sliding way can ensure that the crystals of the antifreeze can enter the inner tube 503 for sealing when the end of the elastic sampling tube 601 is flush with the end of the insertion tube 501;

after the antifreeze solution is crystallized in the inner tube 503, the opening of the inner tube 503 is blocked by the elastic sampling tube 601, and then the control rod 202 is slid upward to make the stirring plate 201 far away from the uppermost end of the antifreeze solution liquid surface, so that when the insertion tube 501 is pulled out from the control rod 202, the antifreeze solution material in the mixing tank 101 is not carried out, and the cleanness of the device is improved.

Claims (10)

1. The antifreeze fluid processing technology is characterized in that: the method comprises the following steps:

s1: pouring an antifreeze solution material into a storage part in a crystallization device, and then placing the storage part in a low-temperature environment;

s2: stirring in the storage part by using a mixing part in the crystallization device to uniformly mix all components of the antifreeze solution, so as to avoid low-temperature crystallization of a single material;

s3: the mixing part is used for fishing the crystallized macromolecular materials in the stirring process in the storage part, and finally, the optimization scheme of the anti-freezing solution can be analyzed according to the types of the detected and fished materials.

2. The antifreeze fluid processing technology according to claim 1, wherein: the crystallization device comprises a storage part for storing each raw material of the antifreeze solution and a mixing part capable of stirring in the storage part, wherein the mixing part is used for fishing large-particle crystals in the antifreeze solution by changing the aperture of the material to enter and exit.

3. The antifreeze fluid processing technology according to claim 2, wherein: the storage part comprises a mixing tank (101), infusion tubes (102) and a sliding groove plate (103), the two infusion tubes (102) are mounted on the mixing tank (101), the infusion tubes (102) are communicated with the mixing tank (101), plugs are mounted on the infusion tubes (102), the sliding groove plate (103) is arranged on the side part of the mixing tank (101), and the mixing part is connected in the sliding groove plate (103).

4. The antifreeze fluid processing technology according to claim 3, wherein: the mixing part comprises a mixing plate (201), a control rod (202) and a baffle (203), the control rod (202) is installed on the mixing plate (201), the baffle (203) is installed on the control rod (202), a baffle edge (204) is arranged on the baffle (203), the baffle (203) is attached to the sliding groove plate (103), the baffle edge (204) is sleeved on the sliding groove plate (103), and the mixing plate (201) can be attached to the inner side of the mixing tank (101).

5. The antifreeze fluid processing technology according to claim 4, wherein: the stirring plate (201) is provided with a plurality of circulation ports (206) which penetrate through two ends of the stirring plate (201), and the circulation ports (206) are arranged.

6. The antifreeze fluid processing technology according to any one of claims 4 to 5, wherein: the stirring plate (201) is hollow inside, a mounting window (205) is arranged on the stirring plate (201), a permeable membrane is mounted at the mounting window (205), an elastic valve (207) which is inwardly contracted is mounted at a circulating port (206), the control rod (202) is hollow inside, the control rod (202) is communicated with the stirring plate (201) inside, and a sampling assembly is mounted in the control rod (202).

7. The antifreeze fluid processing technology according to claim 6, wherein: mixing tank (101) comprises two half tank pieces concatenation, and equal symmetrical two concatenation pieces (104) of installing on every half tank piece are provided with a plurality of perforation (105), and perforation (105) through retaining member (106) run through on two half tank pieces are with the straining between two half tank pieces.

8. The antifreeze fluid processing technology according to claim 6, wherein: an observation pipe (107) is arranged on the mixing tank (101), and two ends of the observation pipe (107) are communicated with the mixing tank (101).

9. The antifreeze fluid processing technology according to claim 8, wherein: an air pipe (108) is communicated with the infusion pipe (102) positioned at the upper side, a one-way valve is arranged on the air pipe (108), and a filling component is arranged on the infusion pipe (102).

10. The antifreeze fluid prepared by the antifreeze fluid processing technology of any one of claims 7 or 9, wherein the antifreeze fluid comprises the following components: according to the mass parts, 30 parts of ethylene glycol, 2 parts of triethanolamine, 3 parts of hydrolyzed maleic anhydride, 2 parts of EDTA and 100 parts of water are taken.

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