CN112094452A

CN112094452A - Preparation method of high polymer material radiator

Info

Publication number: CN112094452A
Application number: CN201910524578.XA
Authority: CN
Inventors: 姜东�
Original assignee: Kaisen Water Heating Equipment Factory In Huancui District
Current assignee: Kaisen Water Heating Equipment Factory In Huancui District
Priority date: 2019-06-18
Filing date: 2019-06-18
Publication date: 2020-12-18

Abstract

The invention discloses a preparation method of a heating radiator, which comprises the following steps: (1) heating and melting (2) a PERT-I type material and a PERT-II type material to form a radiator and a first radiator head and a second radiator head which are provided with radiator joint inner cavities by injection molding; (3) cutting the radiator by using a cutting device; (4) forming a radiator unit by welding a first radiator head, a second radiator head and a radiator through hot melting; (5) connecting the radiator units in series by hot-melt welding to form a complete radiator; (6) and carrying out a pressure measurement test on the whole heating radiator. The production method of the invention has low cost and simple process flow; the product manufactured by the method has good anti-seepage effect, and can reduce the hidden danger of safety accidents; the material has high heat dissipation efficiency, can be recycled, is high temperature resistant and corrosion resistant, has a service life of 50 years, and has high economic value and practical value.

Description

Preparation method of high polymer material radiator

Technical Field

The invention relates to a preparation method of a heating radiator, in particular to a preparation method of a heating radiator made of high polymer materials.

Background

The radiators on the market are mostly made of cast iron radiators, steel radiators, pure copper radiators, copper-aluminum composite radiators, steel-aluminum composite radiators and cast-aluminum composite radiators, and the radiators made of the above materials have high cost; various metal sheets made of traditional materials are not smooth inside, influence flow velocity, are easy to adhere impurities, are easy to scale, are afraid of chemical corrosion of salt, acid, alkali and the like, have increasingly poor effects at the later stage of 3-5 years of use, even have the phenomena of blockage, leakage, paint falling on the surface, rusting and the like, can worry about the problems of corrosion leakage and the like of a heating radiator at home when the radiator is subjected to water pressure test every winter, have high requirements on water quality, are easy to corrode, are easy to oxidize and rust, and influence service life; pollution is easy to generate in the manufacturing process, so that a radiator with low cost, environmental protection and corrosion resistance is urgently needed to meet the daily requirements of people.

The polyphenylene sulfide plastic radiator disclosed in patent CN20301122U cannot meet the requirement of cost saving due to rare raw materials and high cost, and the radiator has low heat transfer efficiency; the patent CN108215050A discloses a light-weight corrosion-resistant HDPE radiator, which has a relatively high density and a relatively poor heat dissipation effect.

Disclosure of Invention

In order to solve the problems, the technical scheme mainly provides the polymer material environment-friendly heating radiator which is simple in process flow, high in heat dissipation capacity of the heating radiator, low in cost, good in stress cracking resistance and long in service life of 50 years.

The technical scheme adopted by the invention comprises the following steps:

(1) mixing a PERT-I type material and a PERT-II type material, heating and melting to obtain a high polymer material;

(2) injection molding a heating radiator made of a heated and melted high polymer material, and a first heating radiator head and a second heating radiator head which are provided with corresponding heating radiator joint inner cavities;

(3) cutting the radiator by using a cutting device;

(4) forming a radiator unit by welding a first radiator head, a second radiator head and a radiator through hot melting;

(5) serially welding the radiator units to form a radiator group;

(6) and carrying out pressure measurement test on the radiator set.

Preferentially, in the step (1), the mass ratio of the PERT-I type material to the PERT-II type material is 40%: 60 percent.

Preferably, in the step (1), a certain proportion of color master is added.

Preferably, in the step (2), the radiator is in a round tube shape.

Preferably, in the step (3), the cutting length of the heating radiator is 43.9 cm.

Preferably, in the step (4), the temperature of the hot-melt welding is controlled to be 270-290 ℃ (winter), 210-240 ℃ (summer) and 250-260 ℃ (spring and autumn).

Preferably, in the step (5), the hot-melting welding temperature is controlled to be 260-280 ℃ (winter), 200-230 ℃ (summer) and 240-250 ℃ (spring and autumn).

Preferably, in the step (6), the pressure measuring environment is water temperature of 80 ℃ and pressure of 1.1 Mpa.

Advantageous effects

Through careful process steps, the leakage of a welding interface can be well prevented by controlling key processes, particularly technical parameters on the welding process technology, and the hidden danger of safety accidents is reduced;

the radiator head and the radiator made by the method are both formed by injection molding, the production flow is simple, the production efficiency is improved, the production cost is reduced, and the material is light and convenient to transport and install;

the heat dissipation capacity of the radiator device manufactured by the method is 1521W/m, which is much higher than that of similar materials, the heat dissipation is uniform, the heat dissipation efficiency is high, and the heat dissipation effect is good;

the radiator manufactured by the method has good flexibility, creep resistance, flexibility, elongation, impact resistance, especially chemical resistance and high-frequency insulation resistance, and can be safely used for more than 50 years under the conditions that the working temperature is 70 ℃ and the working pressure is 0.8 mpa;

the radiator manufactured by the method has excellent chemical resistance corrosion, the environment and the water quality around the radiator do not need to be considered particularly carefully during construction, and the environmental stress resistance is strong;

the heating radiator manufactured by the method can be recycled by a hot melting technology, is energy-saving and environment-friendly, has practicability and has higher economic value;

the radiator made by the method has the high-quality performances of low temperature resistance, corrosion resistance, high elasticity, freezing resistance and the like, and is suitable for being installed and used in cold regions, particularly northeast regions.

Drawings

Fig. 1 is a schematic view of a process flow structure of a method for manufacturing a polymer material radiator of the present invention.

Fig. 2 is a schematic top view structure diagram of a radiator head formed by injection molding according to the method for manufacturing a polymer material radiator.

Fig. 3 is a schematic view of a bottom view of a radiator head formed by injection molding according to a method for manufacturing a polymer material radiator.

Fig. 4 is a schematic structural diagram of a heating radiator unit manufactured from a radiator head by the method for manufacturing a high polymer material heating radiator of the present invention.

Fig. 5 is a schematic structural diagram of a heating radiator made of polymer material from a heating radiator unit to the whole heating radiator.

In the figure: 1. a first radiator head; 2. a second radiator head; 3. a first radiator; 4. a second radiator; 5. a first interface of a radiator head; 6. a second connector of the radiator head; 7. heat dissipation holes; 8. a pipe insert; 9. a radiator joint first inner cavity 10 and a radiator joint second inner cavity; 11. the third radiator head; 12. a radiator unit; 13. and (4) a metal bolt.

Detailed Description

It is to be noted that terms such as first and second, and the like, herein are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. The following will explain the manufacturing method of the present invention in detail with reference to the specific embodiments to further understand the present invention:

example 1:

(1) mixing a PERT-I type material and a PERT-II type material according to the proportion of 40%: mixing 60% of the components in percentage by mass, and heating and melting the mixture to obtain a high polymer material;

(2) adding the polymer material obtained in the step (1) into color master batch;

(3) the high polymer material obtained in the step (1) is injected into a first heating radiator 3 and a second heating radiator 4 in a circular tube shape;

(4) the high polymer material obtained in the step (1) is subjected to injection molding to form a first radiator head 1 and a second radiator head 2 which are correspondingly arranged in a first cavity 9 of a radiator joint and a second cavity 10 of the radiator joint;

(5) cutting the radiator by a cutting device to obtain a radiator with the length of 43.9 cm;

(6) a first radiator leader 1 and a second radiator leader 2 are correspondingly placed on a hot-melt welding device for fixing, a first radiator 3 and a second radiator 4 are placed on the hot-melt welding device for fixing, the first radiator leader 1 is connected with a first inner cavity 9 corresponding to one end of the first radiator 3, the first radiator leader 1 is connected with a second inner cavity 10 opposite to one end of the second radiator 4, correspondingly, the second radiator leader 2 is connected with the first inner cavity 9 corresponding to the other end of the first radiator 3, the second radiator leader 1 is connected with a second inner cavity 10 opposite to the other end of the second radiator 4, and the first radiator leader 1 and the second radiator leader 2 are welded together with the first radiator 3 and the second radiator 4 through alignment checking, heating melting, butt joint and cooling to form a radiator unit 12;

(7) adjusting the temperature of the hot melting welding device to 270 ℃ (winter), 210 ℃ (summer) and 250 ℃ (spring and autumn);

(8) correspondingly placing the two radiator units 12 in the step (6) on hot melting equipment for fixing, wherein a first connector 1 of a first radiator head 1 and a first connector 5 of a second radiator head 2 of each radiator unit correspond to a second connector 6 of a first radiator head 1 and a second connector 6 of a second radiator head 2 of another radiator unit respectively, and a plurality of radiator units are connected through alignment checking, heating melting, butt joint and cooling to form a complete radiator, the number of the radiator units can be set according to needs, wherein the connector of the radiator head of the radiator unit at the outermost radiator unit can be in hot melting connection with other radiator pipelines through a pipeline insert 8 or can achieve a sealing effect directly through setting the pipeline insert 8 and a metal bolt 13;

(9) adjusting the temperature of the hot-melting welding device in the step (7) to 260 ℃ (winter), 200 ℃ (summer) and 240 ℃ (spring and autumn);

(10) carrying out a pressure measurement test on the whole heating radiator;

(11) and (3) the pressure measuring environment in the step (9) is water temperature of 80 ℃ and pressure of 1.1Mpa, and the radiator has no leakage.

Example 2

(6) a first radiator leader 1 and a second radiator leader 2 are correspondingly placed on a hot-melt welding device to be fixed, a first radiator 3 and a second radiator 4 are placed on the hot-melt welding device to be fixed, the first radiator leader 1 is connected with a first inner cavity 9 corresponding to one end of the first radiator 3, the first radiator leader 1 is connected with a second inner cavity 10 opposite to one end of the second radiator 4, correspondingly, the second radiator leader 2 is connected with the first inner cavity 9 corresponding to the other end of the first radiator 3, the second radiator leader 1 is connected with a second inner cavity 10 opposite to the other end of the second radiator 4, and the first radiator leader 1 and the second radiator leader 2 are welded together with the first radiator 3 and the second radiator 4 through alignment checking, heating melting, butt joint and cooling to form a radiator unit 12;

(7) adjusting the temperature of the hot melting welding device to 280 ℃ (winter), 225 ℃ (summer) and 255 ℃ (spring and autumn);

(8) correspondingly placing the two radiator units 12 in the step (6) on hot melting equipment for fixing, wherein a first connector 1 of a first radiator head 1 and a first connector 5 of a second radiator head 2 of one radiator unit correspond to a second connector 6 of a first radiator head 1 and a second connector 6 of a second radiator head 2 of the other radiator unit respectively, and a plurality of radiator units are connected through alignment checking, heating melting, butt joint and cooling to form a complete radiator, and the number of the radiator units can be set according to needs, wherein the connector of the radiator head of the radiator unit at the most lateral side of the radiator can be in hot melting connection with other radiator pipelines through a pipeline insert 8 or can be directly sealed by setting the pipeline insert 8 and a metal bolt 13;

(9) adjusting the temperature of the hot melting welding device to 270 ℃ (winter), 215 ℃ (summer) and 245 ℃ (spring and autumn) in the step (7);

(10) carrying out a pressure measurement test on the whole heating radiator;

Example 3

(7) adjusting the temperature of the hot melting welding device to 290 ℃ (winter), 240 ℃ (summer) and 260 ℃ (spring and autumn);

(8) correspondingly placing the two radiator units 12 in the step (6) on hot melting equipment for fixing, wherein a first connector 1 of a first radiator head 1 and a first connector 5 of a second radiator head 2 of one radiator unit correspond to a second connector 6 of a first radiator head 1 and a second connector 6 of a second radiator head 2 of the other radiator unit respectively, and a plurality of radiator units are connected through alignment checking, heating melting, butt joint and cooling to form a complete radiator, and the number of the radiator units can be set according to needs, wherein the connector of the radiator head of the radiator unit at the most lateral side of the radiator can be in hot melting connection with other radiator pipelines through a pipeline insert 8 or can achieve a sealing effect directly through setting the pipeline insert 8 and a metal bolt 15;

(9) adjusting the temperature of the hot melting welding device to 280 ℃ (winter), 230 ℃ (summer) and 250 ℃ (spring and autumn);

(10) carrying out a pressure measurement test on the whole heating radiator;

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A preparation method of a high polymer material radiator comprises the following steps:

(3) cutting the radiator by using a cutting device;

(5) welding the radiator units to form a complete radiator;

(6) and carrying out a pressure measurement test on the whole heating radiator.

2. The method for manufacturing a polymer material radiator according to claim 1, wherein in the step (1), the mass ratio of the PERT-I type material to the PERT-II type material is 40%: 60 percent.

3. The method for preparing a polymer material radiator according to claim 1, wherein in the step (1), a certain proportion of color masterbatch is added.

4. The method for preparing a polymer material radiator according to claim 1, wherein in the step (2), the radiator is in a shape of a round tube.

5. The method for preparing a polymer material radiator according to claim 1, wherein in the step (3), the length of the radiator cut is 43.9 cm.

6. The preparation method of the polymer material heating radiator according to claim 1, wherein in the step (4), the temperature of the hot-melting welding is controlled to be 270-290 ℃ (winter), 210-240 ℃ (summer) and 250-260 ℃ (spring and autumn).

7. The preparation method of the polymer material radiator of claim 1, wherein in the step (5), the temperature of the hot-melt welding is controlled to be 260-280 ℃ (winter), 200-230 ℃ (summer) 240-250 ℃ (spring and autumn).

8. The method for manufacturing a polymer material radiator according to claim 1, wherein in the step (6), the pressure measurement environment is water temperature of 80 ℃ and pressure of 1.1 Mpa.