阅读说明：本技术 Esepi预制保温直埋耐热高密度聚乙烯低温供热复合管 (ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe ) 是由 崔健伟 张喜宝 姜洪坤 范占新 王贤旸 于 2021-08-31 设计创作，主要内容包括：本发明公开了一种ESEPI预制保温直埋耐热高密度聚乙烯低温供热复合管,由外护管、保温层和工作管组成,其外护管为高密度聚乙烯管材,保温层为硬质聚氨酯泡沫塑料,工作管为耐热聚乙烯(PE-RT II型)管材。本发明制得的ESEPI预制保温直埋耐热高密度聚乙烯低温供热复合管,具有优异的耐热性、耐腐蚀性、耐冲击性、密封性,施工维修方便,减少输送环节热量损失,使用寿命长,适用于集中供热的二次管网系统,生活,空调、太阳能等冷热水系统。(The invention discloses an ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe which comprises an outer protection pipe, a heat preservation layer and a working pipe, wherein the outer protection pipe is a high-density polyethylene pipe, the heat preservation layer is hard polyurethane foam plastic, and the working pipe is a heat-resistant polyethylene (PE-RT II type) pipe. The ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe prepared by the invention has excellent heat resistance, corrosion resistance, impact resistance and sealing property, is convenient to construct and maintain, reduces the heat loss in a conveying link, has long service life, and is suitable for secondary pipe network systems of centralized heat supply, cold and hot water systems of life, air conditioners, solar energy and the like.)

1. An ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe is characterized by comprising an outer protective pipe, a heat-preservation layer and a working pipe;

the outer protective pipe is a high-density polyethylene pipe;

the heat-insulating layer is made of rigid polyurethane foam;

the working pipe is a PE-RT II type heat-resistant polyethylene pipe;

the heat-insulating layer is filled between the outer wall of the working pipe and the inner wall of the outer protective pipe.

2. The ESEPI prefabricated thermal insulation direct-burried heat-resistant high-density polyethylene low-temperature heat supply composite pipe according to claim 1, wherein the high-density polyethylene pipe is made of high-density polyethylene resin;

the high density polyethylene resin comprises a PE100 grade polyethylene resin.

3. The ESEPI prefabricated heat-insulating direct-burial heat-resisting high-density polyethylene low-temperature heat supply composite pipe as claimed in claim 1, wherein the rigid polyurethane foam is prepared from two components, namely black materials and white materials;

the black material is polyisocyanate;

the white material is a polyol composition.

4. The ESEPI prefabricated insulated direct-burried heat-resistant high-density polyethylene low-temperature heating composite pipe according to claim 3, wherein the polyisocyanate comprises polymeric MDI.

5. The ESEPI prefabricated heat-insulating direct-burial heat-resistant high-density polyethylene low-temperature heat supply composite pipe as claimed in claim 3, wherein the polyol composition is prepared from the following raw materials in parts by weight: 30-50 parts of polyether polyol, 10-30 parts of polyester polyol, 10-30 parts of foaming agent, 2-4 parts of foaming stabilizer, 0.5-1.5 parts of foaming catalyst, 5-15 parts of flame retardant and 10-25 parts of expandable graphite;

the preparation method comprises the following steps:

and uniformly mixing the polyester polyol, the polyether polyol and the expandable graphite, adding the foaming agent, the foaming stabilizer, the flame retardant and the foaming catalyst, and uniformly mixing to obtain the polyol composition.

6. The ESEPI prefabricated heat-insulating direct-burial heat-resistant high-density polyethylene low-temperature heat-supply composite pipe according to claim 5,

the polyester polyol comprises at least one of aliphatic polyester polyol and aromatic polyester polyol;

the polyether polyol comprises at least one of a polyoxypropylene polyol or a polytetrahydrofuran polyol;

the blowing agent comprises monofluorodichloroethane;

the foam stabilizer comprises a polysiloxane;

the foaming catalyst comprises at least one of dibutyltin dilaurate, triethylene diamine and triethanolamine;

the flame retardant comprises any one of phosphate flame retardant and phosphite flame retardant.

7. A method for preparing ESEPI prefabricated heat-preservation direct-burial heat-resistant high-density polyethylene low-temperature heat supply composite pipe according to any one of claims 1 to 6, which comprises the following steps:

(1) pretreating the outer wall of the working pipe;

(2) preparing a heat-insulating layer on the outer wall of the pretreated working pipe;

(3) wrapping glass fiber cloth outside the heat-insulating layer;

(4) extruding high-density polyethylene resin outside the heat-insulating layer wrapped with glass fiber cloth to form an outer protective pipe;

(5) cooling and cutting into sections to obtain the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe.

8. The method for preparing the ESEPI prefabricated heat-preservation direct-burial heat-resistant high-density polyethylene low-temperature heat-supply composite pipe according to claim 7, wherein the step (2) of preparing the heat-preservation layer specifically comprises the following steps:

1) fixing the working pipe;

2) mixing the black material and the white material according to a certain proportion, spraying the mixture on the outer wall of the working pipe, and expanding the foam volume;

3) cutting and shaping after the foam volume on the outer wall of the working pipe stops expanding to obtain a heat insulation layer with a regular shape;

the mixing mass ratio of the black materials to the white materials is 1-1.2: 1.

9. the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe preparation method according to claim 8, characterized in that a heat-preservation pipe rigid polyurethane foam heat-preservation layer forming device is adopted to form a heat-preservation layer outside a working pipe, and the heat-preservation pipe rigid polyurethane foam heat-preservation layer forming device comprises a guide rail fixing seat (1), a black material storage tank (2) and a white material storage tank (3);

a central driving guide rail (11) is arranged in the center of the guide rail fixing seat (1), and side driving guide rails (12) are arranged on two sides of the guide rail fixing seat (1);

the two pipeline fixing seats (4) are arranged in the central driving guide rail (11) in a sliding mode, and the central driving guide rail (11) is used for driving the two pipeline fixing seats (4) to move respectively;

the sprayer (5) and the cutter (6) are arranged in the side driving guide rail (12) in a sliding mode, and the side driving guide rail (12) is used for driving the sprayer (5) and the cutter (6) to move respectively;

the pipeline fixing seat (4) is used for clamping a pipeline, and the pipeline fixing seat (4) is also used for driving the pipeline to rotate circumferentially;

the sprayer (5) is respectively connected with the black material storage tank (2), the white material storage tank (3) and the air compressor, and the sprayer (5) is used for spraying hard polyurethane foam to a pipeline;

the cutter (6) is used for cutting and shaping the rigid polyurethane foam after spraying and curing.

Technical Field

The invention relates to the technical field of prefabricated heat-preservation direct-buried pipelines, in particular to an ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe.

Background

The heating season in northern areas of China is 11 months to 3 months in the next year, the energy loss of a heating system is mainly reflected in low heat utilization efficiency, wherein the loss in a pipe network accounts for more than 20% of the energy loss, and the energy waste is serious. The traditional steel pipe is adopted as a heat supply pipe, and the problems of non-corrosion resistance, short service life, high maintenance cost and the like exist.

The high-density polyethylene direct-buried prefabricated heat-insulating pipe is a good novel pipe material which appears internationally in recent years, and is widely applied due to good heat insulation, corrosion resistance and mechanical properties. The high-density polyethylene pipe is used as an outer protective pipe of the heat-insulating pipe, the heat-resistant polyethylene pipe is used as a working pipe, and the polyurethane hard foam is used as a heat-insulating layer material of the heat-insulating pipe, so that the heat-insulating pipe has the advantages of corrosion resistance and prolonged service life. However, the properties of the rigid polyurethane foam and the formation mode of the heat-insulating layer directly affect the service performance and the service life of the heat-insulating pipe. If the density of the polyurethane rigid foam is too low, the heat-insulating layer is easy to be carbonized, and the heat-insulating effect is influenced; or the polyurethane hard foam is injected by adopting the traditional pipe-in-pipe process, so that the problems that the polyurethane foam is not uniformly molded, a local cavity is easily caused, the heat insulation performance of the heat insulation pipe is influenced and the like exist.

Disclosure of Invention

Based on the defects in the prior art, the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe has the characteristics of excellent heat resistance, corrosion resistance, impact resistance, sealing property, convenience in construction and maintenance, reduction in heat loss in a conveying link, long service life and the like.

In order to solve the technical problems, the technical scheme adopted by the invention is as follows:

an ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe comprises an outer protective pipe, a heat-preservation layer and a working pipe;

the outer protective pipe is a high-density polyethylene pipe;

the heat-insulating layer is made of rigid polyurethane foam;

the working pipe is a PE-RT II type heat-resistant polyethylene pipe;

the heat-insulating layer is filled between the outer wall of the working pipe and the inner wall of the outer protective pipe.

The special molecular branch distribution structure of the second type heat-resistant polyethylene (PE-RT II) pipe formed by copolymerizing high-density polyethylene and hexene ensures that the PE-RT II type heat-resistant polyethylene pipe has excellent crack resistance, high temperature resistance and antistatic hydraulic strength; has weldability, and can be used in all welding methods.

Preferably, the high density polyethylene pipe is made of a high density polyethylene resin;

the high density polyethylene resin comprises a PE100 grade polyethylene resin.

Preferably, the rigid polyurethane foam is prepared from two components, namely black material and white material;

the black material is polyisocyanate;

the white material is a polyol composition.

Preferably, the polyisocyanate comprises polymeric MDI.

Preferably, the polyol composition comprises the following raw materials in parts by weight: the polyol composition is prepared from the following raw materials in parts by weight: 30-50 parts of polyether polyol, 10-30 parts of polyester polyol, 10-30 parts of foaming agent, 2-4 parts of foaming stabilizer, 0.5-1.5 parts of foaming catalyst, 5-15 parts of flame retardant and 10-25 parts of expandable graphite;

the preparation method comprises the following steps:

the preparation method comprises the following steps of uniformly mixing polyester polyol, polyether polyol and expandable graphite, adding a foaming agent, a foaming stabilizer, a flame retardant and a foaming catalyst, and uniformly mixing to obtain a polyol composition, namely a white material.

Preferably, the polyester polyol comprises at least one of aliphatic polyester polyol and aromatic polyester polyol;

the polyether polyol comprises at least one of a polyoxypropylene polyol or a polytetrahydrofuran polyol;

the polyoxypropylene polyol includes a polyoxypropylene diol (PPG);

the polytetrahydrofuran polyol comprises polytetrahydrofuran ether glycol (PTMEG);

the blowing agent comprises monofluorodichloroethane;

the foam stabilizer comprises a polysiloxane;

the foaming catalyst comprises at least one of dibutyltin dilaurate, triethylene diamine and triethanolamine;

the flame retardant comprises any one of phosphate flame retardant and phosphite flame retardant;

the phosphate ester flame retardant comprises triethyl phosphate;

the phosphite flame retardant comprises tris (dipropylene glycol) phosphite.

Preferably, the preparation method of the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe comprises the following steps:

(1) carrying out surface decontamination and cleaning pretreatment on the outer wall of the working pipe;

(2) preparing a heat-insulating layer on the outer wall of the pretreated working pipe;

(3) wrapping glass fiber cloth with the thickness of 1-5mm outside the heat-insulating layer;

(4) extruding high-density polyethylene resin outside the heat-insulating layer wrapped with glass fiber cloth to form an outer protective pipe;

(5) cooling and cutting into sections to obtain the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe.

Preferably, the preparation of the heat-insulating layer in the step (2) specifically comprises the following steps:

1) fixing the working pipe;

2) mixing the black material and the white material according to a certain proportion, spraying the mixture on the outer wall of the working pipe, and expanding the foam volume;

3) cutting and shaping after the foam volume on the outer wall of the working pipe stops expanding to obtain a heat insulation layer with a regular shape;

the mixing mass ratio of the black materials to the white materials is 1.0-1.2: 1.

compared with the prior art, the invention has the following beneficial effects:

1. according to the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe, the outer protective pipe is made of high-density polyethylene pipes, the heat-preservation layer is made of hard polyurethane foam plastics, the working pipe is made of imported PE-RT II type heat-resistant polyethylene pipes, the using temperature is-50-110 ℃, the minimum working temperature of long-term working is-30 ℃ and the maximum working temperature is 95 ℃, and the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe has the characteristics of excellent impact resistance and cracking resistance, strong corrosion resistance, long service life and good heat preservation performance.

2. In addition, by designing the components of the white material and the mixing ratio of the white material and the black material, the formed hard polyurethane foam has higher density which is not less than 60kg/m³The pore wall of the foam pore is thick enough to support the pressure difference effect in the curing process, and the molding shrinkage is small and is lower than 1%; the prepared foam heat-insulating layer has high hardnessAnd when the high-density polyethylene outer protective pipe is subsequently extruded, the heat-insulating layer cannot be extruded and deformed.

3. According to the invention, before the high-density polyethylene resin is extruded to form the outer protective pipe, the glass fiber cloth is coated outside the rigid polyurethane foam heat-insulating layer, and the glass fiber cloth has a good heat-insulating effect, so that the high-density polyethylene resin which is melted at high temperature can be effectively prevented from being directly extruded to the surface of the heat-insulating layer, and the rigid polyurethane foam is decomposed, carbonized, collapsed on the surface and the like, so that the conditions that the shape of the outer protective pipe of the heat-insulating pipe is not standard, the heat-insulating effect is reduced or lost and the like are caused.

4. According to the invention, the heat-insulating layer is formed outside the working pipe by adopting the heat-insulating pipe rigid polyurethane foam heat-insulating layer forming device, so that the thickness of the rigid polyurethane foam heat-insulating layer can be randomly adjusted according to requirements, and uniform spraying is carried out according to the required thickness, so that foam on the heat-insulating pipe is uniformly distributed, and the waste of rigid polyurethane foam is reduced; in addition, the pipeline coated with the foam is cut and shaped, so that the appearance of the pipeline coated with the foam is regular, the fit between the outer pipe of the heat-insulating pipe and the pipeline coated with the foam is ensured, and the problems that when rigid polyurethane foam is injected into cavities of a working pipe and an outer protecting pipe at one time, the foam is easy to cure when not reaching a set part, the polyurethane foam is uneven in molding, local cavities are easily caused, and the heat-insulating performance of the heat-insulating pipe is influenced are solved.

Drawings

FIG. 1 is a schematic cross-sectional view of an ESEPI prefabricated heat-insulating direct-buried heat-resistant high-density polyethylene low-temperature heat-supply composite pipe according to the present invention;

FIG. 2 is a schematic perspective view of an apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 3 is a second schematic perspective view of the apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 4 is a schematic perspective view of a blacking material storage tank of the device for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 5 is a schematic perspective view of a pipe fixing seat of the device for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 6 is a front view of a pipe fixing seat of the device for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 7 is a schematic perspective view of a sprayer of the apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 8 is an enlarged view of portion A of FIG. 7 in accordance with the present invention;

FIG. 9 is a schematic sectional view of a sprayer of the apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention;

FIG. 10 is a schematic sectional view showing a single nozzle and a mixing chamber of the apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention

FIG. 11 is a partially cut-away schematic view of a single nozzle and a mixing chamber of the device for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention

FIG. 12 is a schematic perspective view of a cutter of the apparatus for forming a rigid polyurethane foam insulation layer of an insulation pipe according to the present invention.

In the figure: 1. a guide rail fixing seat; 11. a central drive rail; 12. a side drive rail; 2. a black material storage tank; 3. a white material storage tank; 4. a pipeline fixing seat; 41. a driven connecting seat; 42. fixing the side ring; 43. rotating the clamping ring; 431. a toothed ring; 432. a holder; 433. a first electric telescopic rod; 434. a rubber collet; 44. a drive motor; 441. a gear; 5. a sprayer; 51. a support ring; 52. a support frame; 53. a foam nozzle; 531. a nozzle; 532. a mixing chamber; 533. an air inlet interface; 534. a black material interface; 535. a white material interface; 536. a spiral flow channel; 537. a separation baffle; 6. a cutter; 61. a fixed frame; 62. a mounting ring; 63. a second electric telescopic rod; 64. a cutting blade; 101. a working pipe; 102. a heat-insulating layer; 103. glass fiber cloth; 104. an outer protecting pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Preparation of white materials in the components of the rigid polyurethane foam:

comprises the following raw materials:

30 parts of polypropylene oxide glycol, 10 parts of aliphatic polyester polyol, 10 parts of monofluoro dichloroethane, 2 parts of polysiloxane, 0.5 part of dibutyltin dilaurate, 5 parts of triethyl phosphate and 10 parts of expandable graphite;

the preparation method comprises the following steps:

uniformly mixing aliphatic polyester polyol, polyoxypropylene glycol and expandable graphite, adding monofluorodichloroethane, polysiloxane, triethyl phosphate and dibutyltin dilaurate, and uniformly mixing to obtain a polyol composition, namely a white material;

preparing a high-density polyethylene pipeline for coiled high-toughness spray irrigation:

(1) carrying out surface decontamination and cleaning pretreatment on the outer wall of the PE-RT II type heat-resistant polyethylene pipe;

(2) preparing a heat-insulating layer on the outer wall of the pretreated working pipe:

1) fixing the working pipe;

2) mixing the black material and the white material according to the mass ratio of 1:1, spraying the mixture on the outer wall of the working pipe, and expanding the foam volume;

3) cutting and shaping after the foam volume on the outer wall of the working pipe stops expanding to obtain a heat insulation layer with a regular shape;

(3) wrapping glass fiber cloth with the thickness of 3mm outside the heat preservation layer;

(4) extruding high-density polyethylene resin outside the heat-insulating layer wrapped with glass fiber cloth to form an outer protective pipe;

(5) cooling and cutting into sections to obtain the ESEPI prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe.

Example 2

Preparation of white materials in the components of the rigid polyurethane foam:

comprises the following raw materials:

50 parts of polytetrahydrofuran ether glycol, 30 parts of aromatic polyester polyol, 30 parts of monofluoro dichloroethane, 4 parts of polysiloxane, 1.5 parts of triethylene diamine, 15 parts of tris (dipropylene glycol) phosphite ester and 25 parts of expandable graphite;

the preparation method comprises the following steps:

uniformly mixing aromatic polyester polyol, polytetrahydrofuran ether glycol and expandable graphite, adding monofluorodichloroethane, polysiloxane, tri (dipropylene glycol) phosphite ester and triethylene diamine, and uniformly mixing to obtain a polyol composition, namely a white material.

The procedure for preparing a coiled high-tenacity high-density polyethylene pipe for sprinkling irrigation was the same as in example 1.

Example 3

Comprises the following raw materials:

20 parts of polypropylene oxide glycol, 20 parts of polytetrahydrofuran ether glycol, 10 parts of aliphatic polyester polyol, 10 parts of aromatic polyester polyol, 20 parts of monofluoro dichloroethane, 3 parts of polysiloxane, 1 part of triethanolamine, 5 parts of triethyl phosphate, 5 parts of tris (dipropylene glycol) phosphite and 15 parts of expandable graphite;

the preparation method comprises the following steps:

the preparation method comprises the steps of uniformly mixing aliphatic polyester polyol, aromatic polyester polyol, polypropylene oxide glycol, polytetrahydrofuran ether glycol and expandable graphite, adding monofluoro dichloroethane, polysiloxane, triethyl phosphate, tris (dipropylene glycol) phosphite and triethanolamine, and uniformly mixing to obtain a polyol composition, namely a white material.

The procedure for preparing a coiled high-tenacity high-density polyethylene pipe for sprinkling irrigation was the same as in example 1.

In examples 1-3, the black material selected was PM200 type polymeric MDI, Tantario TM; the selected aliphatic polyester polyol is aliphatic polyester polyol PL-2000; the selected aromatic polyester polyol is phthalic anhydride polyester polyol (hydroxyl value is 360-400 mgKOH/g, acid value is less than or equal to 2.0mgKOH/g, water content is less than or equal to 0.1%, viscosity is less than or equal to 4000mPa & s, plastic factory of Jinling petrochemical company); the selected polyoxypropylene diol is polyoxypropylene diol PPG-3000, and the selected polytetrahydrofuran polyol is polytetrahydrofuran ether diol PTMEG-2000; the scale size of the expandable graphite is 80 meshes; the polysiloxane selected was a modified polysiloxane ZX-101B (Zhongxing Silicone science Co., Ltd., Lyyang).

Comparative example 1

In comparison with example 1, in the case of the white material prepared in comparative example 1, no foam stabilizer was added, and the other conditions were not changed.

Comparative example 2

Compared with the embodiment 1, in the comparative example 2, after the heat insulation layer is prepared, the high-density polyethylene resin is directly extruded outside the heat insulation layer without wrapping glass fiber cloth, and other conditions are unchanged.

Example 4

The embodiment discloses a device for forming a rigid polyurethane foam heat-insulating layer of a heat-insulating pipe, and the heat-insulating layer of the ESEPI prefabricated heat-insulating direct-buried heat-resisting high-density polyethylene low-temperature heat supply composite pipe is prepared in the device in the embodiments 1-3.

As shown in fig. 2-12, a molding device for a rigid polyurethane foam insulation layer of an insulation pipe comprises a guide rail fixing seat 1, a black material storage tank 2 and a white material storage tank 3, wherein a central driving guide rail 11 is arranged in the center of the guide rail fixing seat 1, and side driving guide rails 12 are arranged on both sides of the guide rail fixing seat 1; the central driving guide rail 11 is internally provided with two pipeline fixing seats 4 in a sliding manner, and the central driving guide rail 11 is used for driving the two pipeline fixing seats 4 to move respectively; the sprayer 5 and the cutter 6 are arranged in the side driving guide rail 12 in a sliding mode, and the side driving guide rail 12 is used for driving the sprayer 5 and the cutter 6 to move respectively; the pipeline fixing seat 4 is used for clamping a pipeline, and the pipeline fixing seat 4 is also used for driving the pipeline to rotate circumferentially; the sprayer 5 is respectively connected with the black material storage tank 2, the white material storage tank 3 and the air compressor, and the sprayer 5 is used for spraying hard polyurethane foam to the pipeline; the cutter 6 is used for cutting and shaping the rigid polyurethane foam after spraying and curing.

The central driving guide rail 11 and the side driving guide rail 12 are both electric slide rails, and the electric slide rails drive the pipeline fixing seat 4, the sprayer 5 and the cutter 6 to move in the prior art, which is not described herein again.

Wherein the black material is polyisocyanate, the white material is a polyol composition, and the black material is a mixture composed of polyether polyol, polyester polyol, a foaming agent, a foaming stabilizer, a foaming catalyst, a flame retardant and expandable graphite.

Further, as shown in fig. 7-11, the sprayer 5 includes a support ring 51 and a support frame 52, wherein a plurality of foam nozzles 53 are installed on the support ring 51; one end of the support frame 52 is connected with the support ring 51, the other end of the support frame 52 is connected with the side driving guide rail 12, and the side driving guide rail 12 drives the whole sprayer 5 to move along the side driving guide rail 12 through the support frame 52.

The foam head 53 comprises a nozzle 531 and a mixing chamber 532, the nozzle 531 being arranged inside the support ring 51, the nozzle 531 being directed towards the axial position of the support ring 51.

An air inlet port 533 is arranged on the side surface of the mixing cavity 532, and a black material port 534 and a white material port 535 are arranged on the bottom surface of the mixing cavity 532 away from the nozzle 531; the air inlet interface 533 is connected with an air compressor through a pipeline, the black material interface 534 is communicated with the black material storage tank 2 through a pipeline, and the white material interface 535 is communicated with the white material storage tank 3 through a pipeline.

The black material storage tank 2 is used for quantitatively supplying black materials to the mixing cavity 532 through a black material interface 534, and the white material storage tank 3 is used for quantitatively supplying white materials to the mixing cavity 532 through a white material interface 535; the air compressor provides high-pressure air to the mixing cavity 532 through the air inlet 533, the high-pressure air is used for mixing the black materials and the white materials in the mixing cavity 532, and the high-pressure air is also used for carrying the mixed black materials and white materials to be sprayed out from the nozzle 531.

A spiral flow passage 536 is arranged in the mixing cavity 532, and a separation baffle 537 is arranged at the top end of the spiral flow passage 536; the separation baffle 537 is used for separating the black material interface 534 from the white material interface 535 in the mixing chamber 532, and the spiral flow passage 536 is used for providing a uniform mixing path of the black material and the white material.

When specifically using, black material storage tank 2, 3 bottom ends of white material storage tank all are provided with quantitative discharger, and quantitative discharger all is provided with a plurality of openings, and the quantitative discharger of black material storage tank 2, 3 bottom ends of white material storage tank is used for the ration to pour into quantitative black material and white material in mixing chamber 532.

And in practical application, after the spraying is finished, the black material and white material supply of the black material storage tank 2 and the white material storage tank 3 to the mixing cavity 532 is firstly cut off, so that the high-pressure air passing through the air inlet interface 533 is continuously circulated for a period of time until the black material and the white material inside the mixing cavity 532 are completely sprayed out, and the black material and the white material are prevented from solidifying and forming inside the mixing cavity 532 to block the mixing cavity 532 and the nozzle 531.

Further, as shown in fig. 5 to 6, the pipe fixing base 4 includes a driven connecting base 41, two fixing side rings 42, a rotating clamp ring 43, and two driving motors 44; the bottom ends of the two fixed side rings 42 are respectively fixed with the driven connecting seat 41, and the rotary clamping ring 43 is arranged between the two fixed side rings 42.

The rotary clamping ring 43 is respectively in power connection with the two driving motors 44 through a gear ring 431 and a gear 441, and the two driving motors 44 run synchronously to drive the rotary clamping ring 43 to rotate in the circumferential direction.

A plurality of holders 432 are arranged inside the rotary clamping ring 43, and each holder 432 comprises a first electric telescopic rod 433 and a rubber chuck 434; the movable end of the first electric telescopic rod 433 is fixed with the rubber chuck 434, and the first electric telescopic rod 433 is used for driving the rubber chuck 434 to move.

Further, as shown in fig. 12, the cutter 6 includes a fixed frame 61 and a mount ring 62, the mount ring 62 being disposed at the center of the top end of the fixed frame 61; the fixed frame 61 is used for being connected with the side driving guide rail 12, and the side driving guide rail 12 drives the whole cutter 6 to move along the side driving guide rail 12 through the fixed frame 61; a plurality of second electric telescopic rods 63 are arranged inside the mounting ring 62, a cutting knife 64 is fixedly arranged at the movable end of each second electric telescopic rod 63, the second electric telescopic rods 63 are used for driving the cutting knife 64 to move, and the cutting knife 64 is used for cutting and shaping the cured rigid polyurethane foam.

When the pipe-type heat preservation device is used, a pipeline is installed firstly, the first pipeline installation mode is suitable for forming the short guide rail fixing seat 1 and the heat preservation layer of the prefabricated pipe, and the second pipeline installation mode is suitable for forming the long guide rail fixing seat 1 and the heat preservation layer of the prefabricated pipe. The first pipeline installation mode: firstly pass sprayer 5 with the pipeline to place the pipeline both ends respectively at two pipeline fixing base 4 central authorities, stretch jointly through the first electric telescopic handle 433 of a plurality of holders 432 of pipeline fixing base 4, promote rubber chuck 434 and pipeline contact through first electric telescopic handle 433, and through the pressure that a plurality of first electric telescopic handle 433 provided, make a plurality of rubber chucks 434 with the stable centre gripping of pipeline.

In the first pipeline installation mode, after the pipeline is fixed in the two pipeline fixing seats 4, the two pipeline fixing seats 4 are fixed, the sprayer 5 moves to spray the pipeline, the rotary clamping rings 43 of the two pipeline fixing seats 4 synchronously rotate while the sprayer 5 drives the guide rail 12 to move along the side edge, thereby making the sprayer 5 perform a spiral motion with respect to the pipeline, thereby performing the spraying of the hard polyurethane foam on the surface of the pipeline through the plurality of foam spray heads 53, the guide rail 12 is driven by the slow movement of the entire applicator 5 along the side, and by the slow running fit of the rotating gripper ring 43, the rigid polyurethane foam sprayed by the plurality of foam nozzles 53 can completely cover the circumference of the pipeline, so as to prevent uneven molding of the foam around the pipeline, the multiple foam nozzles 53 are used for overall spraying to jointly cover the heat insulation pipe, so that foam cavities are prevented from being formed, and the heat insulation capacity of the heat insulation pipe is improved.

A second pipeline installation mode: two pipeline fixing base 4 remove one side to central drive guide rail 11 jointly to carry the pipeline to two pipeline fixing base 4 central authorities from this side, after the one end of 4 centre gripping pipelines of pipeline fixing base 4 far away from this side, drive pipeline fixing base 4 and remove to the opposite side along central drive guide rail 11, move to the central authorities of the pipeline fixing base 4 that are nearer apart from this side until the other end of pipeline, the rethread is from the nearer pipeline fixing base 4 of this side with the stable centre gripping of pipeline.

In pipeline installation mode two, the pipeline is after two pipeline fixing base 4 inside fixed completions, sprayer 5 is fixed, two pipeline fixing base 4 drive the pipeline and remove, meanwhile, two pipeline fixing base 4's rotatory grip ring 43 rotates in step, thereby make sprayer 5 make helical motion for the pipeline, thereby carry out the spraying of rigid polyurethane foam through a plurality of foam shower nozzles 53 to the pipeline surface, it removes to drive the pipeline through two pipeline fixing base 4, and the slow normal running fit through rotatory grip ring 43, make a plurality of foam shower nozzles 53 spun rigid polyurethane foam can cover pipeline border is whole, thereby guarantee the comprehensive coverage of foam to pipeline border, prevent that the foam is uneven at the peripheral shaping of pipeline, stop the appearance of foam cavity, improve the heat preservation ability of insulating tube.

In the two installation modes:

the spraying principle of the sprayer 5 is that a quantitative discharger at the bottom end of the black material storage tank 2 and the white material storage tank 3 is used for quantitatively injecting quantitative black material and white material into the mixing cavity 532, and an air compressor provides high-pressure air to the inside of the mixing cavity 532, the high-pressure air carries the black material from the black material interface 534, the high-pressure air carrying the black material flows along the spiral flow channel 536, when the high-pressure air flows along the spiral flow channel 536 and passes through the white material interface 535, the black material and the white material are mixed in different moving directions due to the difference between the moving direction of the white material and the moving direction of the high-pressure air carrying the black material, and the black material and the white material are collided and mixed with the spiral flow channel 536 and move along the spiral flow channel 536 due to the entrainment of the high-pressure air, so that the black material and the white material are sufficiently and uniformly mixed in the mixing cavity 532 to improve the uniformity of foam sprayed from the nozzle 531, the molding effect of the hard polyurethane foam heat-insulating layer is ensured.

The high-pressure air promotes mixing of the black and white materials and ejects the black and white materials from the nozzles 531 toward the axial position of the support ring 51.

The principle that the pipeline fixing seats 4 drive the pipeline to rotate in the circumferential direction is as follows, the driving motors 44 of the two pipeline fixing seats 4 are synchronously started, and the driving motors 44 simultaneously drive the rotary clamping rings 43 of the two pipeline fixing seats 4 to rotate synchronously through the gear rings 431 and the gears 441, so that the pipeline is rotated in the circumferential direction through clamping of the clamping device 432.

After the foam is sprayed on the outer side of the pipeline, the pipeline stays for a period of time to wait for the foam to solidify, the pipeline is driven to move to one side of the cutter 6 by the two pipeline fixing seats 4, the pipeline fixing seat 4 far away from one side of the cutter 6 continues to clamp the pipeline, the pipeline fixing seat 4 near one side of the cutter 6 is shortened by the first electric telescopic rod 433, so that the pipeline fixing seat 4 can clamp the solidified foam pipe by the rubber chuck 434, the pipeline coated with the foam can be driven to move to the direction of the cutter 6 by the two pipeline fixing seats 4, and the pipeline coated with the foam can be driven to rotate in the circumferential direction by the two pipeline fixing seats 4, so that the cutting knife 64 can perform spiral movement relative to the pipeline coated with the foam, the pipeline coated with the foam can be cut and shaped, and the appearance of the pipeline coated with the foam is regular, the joint between the outer pipe of the heat preservation pipe formed by extrusion and the heat preservation layer is ensured.

Before cutting and shaping, the second electric telescopic rod 63 drives the cutting knife 64 to move, so that the diameter of the pipeline coated with the cut foam is changed, and the diameter of the pipeline coated with the foam is convenient to adjust.

Further, when carrying out polyurethane rigid foam shaping to the insulating tube, cooperation through sprayer and pipeline fixing base is operated, it makes spiral motion for the pipeline to get the sprayer, thereby carry out the spraying of polyurethane rigid foam through a plurality of foam shower nozzles to pipeline surface, the foam that a plurality of foam shower nozzles produced at the pipeline outer wall can carry out abundant spraying to the pipeline outer wall, thereby guarantee the comprehensive cover of foam to pipeline border, prevent that the foam is uneven at the peripheral shaping of pipeline, stop the appearance of foam cavity, improve the heat preservation ability of insulating tube.

Further, after the foam solidifies, drive the pipeline through two pipeline fixing bases and remove to cutter one side, and carry out circumference rotation through the pipeline after two pipeline fixing bases drive the cladding foam simultaneously, thereby make the pipeline after the cutter can cladding foam relatively carry out the helical motion, thereby cut the plastic to the pipeline after the cladding foam, thereby make the pipeline appearance after the cladding foam regular, guarantee the laminating between the insulating tube outer tube that crowded package formed and the heat preservation, thereby when guaranteeing fast tooling, guarantee the abundant laminating between each layer of insulating tube, guarantee the heat preservation effect of insulating tube.

Further, through the use of two kinds of pipeline installation modes, pipeline installation mode one is applicable to the heat preservation shaping of shorter guide rail fixing base and prefabricated pipe, and pipeline installation mode two is applicable to longer guide rail fixing base and the heat preservation shaping of tubulation promptly to make this kind of heat preservation pipe polyurethane rigid foam heat preservation forming device can use the service environment of multiple difference, improve the suitability of device.

Test examples

The rigid polyurethane foam plastic heat-insulating layer materials prepared in examples 1-3 and comparative example 1 and the prefabricated heat-insulating direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipes prepared in examples 1-3 and comparative examples 1-2 were tested for various performances:

the test basis of the density, the compressive strength, the thermal conductivity coefficient and the closed cell ratio of the hard polyurethane foam plastic is as follows: according to the regulation in the standard GB/T34611-2017 rigid polyurethane spray polyethylene winding prefabricated direct-buried heat-insulation pipe;

the oxygen index of rigid polyurethane foams is tested according to: reference standard

GB-T2406.2-2009 plastic combustion behavior determination by oxygen index method;

the results of the rigid polyurethane foam performance tests are shown in table 1:

TABLE 1

The prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe has the following performance test bases: the method is carried out according to the regulations in GB/T34611 & lt- & gt 2017 rigid polyurethane spraying polyethylene winding prefabricated direct-buried heat insulation pipe and GB/T29047 & gt 2012 high-density polyethylene outer protection pipe rigid polyurethane foam plastic prefabricated direct-buried pipe and pipe fitting;

the performance test results of the prefabricated heat-preservation direct-buried heat-resistant high-density polyethylene low-temperature heat supply composite pipe are shown in the table 2:

TABLE 2

According to the test results in table 1, the hard polyurethane foam plastic insulation layer materials prepared in examples 1-3 have higher density, compression strength, closed cell rate, lower thermal conductivity and oxygen index, which indicates that the foam has high hardness, high strength, good flame retardant effect and high insulation performance. In comparative example 1, since no foaming stabilizer was added, the surface tension of the system was increased, the pore size was increased, the density of the foam was decreased, the toughness of the pore wall was decreased, and the compressive strength was decreased.

According to the test results in table 2, the prefabricated heat-preservation direct-burial heat-resistant high-density polyethylene low-temperature heat supply composite pipe prepared in the embodiment 1-3 has excellent performance, high surface flatness, strong impact resistance, good temperature resistance and long service life; in comparative example 1, the foam has a large pore size and a low density, and is poor in impact resistance and low in temperature resistance; in comparative example 2, since no glass fiber cloth is used for isolating heat, when the high-density polyethylene melted at high temperature is extruded on the surface of the heat-insulating layer, foam contacted with the heat-insulating layer is decomposed by heat, the volume of the heat-insulating layer shrinks, the shape of an outer protective pipe formed by extrusion is irregular, and the heat-resistant performance is reduced and the service life is shortened due to the damage of the heat-insulating layer.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.