CN110185884B

CN110185884B - Heat transmission energy-saving pipeline

Info

Publication number: CN110185884B
Application number: CN201910485302.5A
Authority: CN
Inventors: 杨胜伟
Original assignee: Hunan Dadao New Energy Development Co Ltd
Current assignee: Hunan Dadao New Energy Development Co Ltd
Priority date: 2019-06-05
Filing date: 2019-06-05
Publication date: 2021-06-08
Anticipated expiration: 2039-06-05
Also published as: CN110185884A

Abstract

The invention provides a heat transmission energy-saving pipeline. The heat transmission energy-saving pipeline comprises a pipeline, a heat insulation mechanism, a fixing mechanism, a filtering mechanism and a limiting mechanism, wherein the heat insulation mechanism is sleeved on the side wall of the pipeline; the fixing mechanism props against the pipeline and is arranged inside the heat preservation mechanism; the filter mechanism is arranged at one end of the pipeline and comprises a fixing ring, a connecting ring, a filter screen and a storage ball, the fixing ring is arranged in the pipeline, the filter screen in a round table shape is arranged at one end of the fixing ring, the connecting ring with an arc-shaped side wall is arranged in the filter screen at equal intervals, and the storage ball is arranged at one end of the filter screen; the limiting mechanism is arranged at the joint of the fixing ring and the pipeline. The heat transmission energy-saving pipeline provided by the invention is convenient for collecting impurities in geothermal water.

Description

Heat transmission energy-saving pipeline

Technical Field

The invention relates to the technical field of thermal transmission, in particular to a thermal transmission energy-saving pipeline.

Background

A pipeline is a device for transporting a gas, liquid or fluid with solid particles, connected by pipes, pipe couplings, valves, etc. The pipeline is widely applied to multiple industries and fields due to the unique characteristics of the pipeline. The use of pipelines is very widespread, mainly in water supply, drainage, heating, gas supply, long-distance oil and gas delivery, agricultural irrigation, hydraulic engineering and various industrial installations.

At the in-process that uses pipeline transportation geothermal water, geothermal water is inside to contain a large amount of impurity, and some impurity deposits in the junction of pipeline inside hot water, cause the inside jam of pipeline, and impurity deposits in the junction of pipeline, makes two pipeline adhesions together, inconvenient people maintain.

Therefore, there is a need to provide a new thermal transmission energy-saving pipeline to solve the above technical problems.

Disclosure of Invention

The invention aims to provide a thermal transmission energy-saving pipeline convenient for collecting impurities.

In order to solve the technical problem, the thermal transmission energy-saving pipeline provided by the invention comprises: the device comprises a pipeline, a heat insulation mechanism, a fixing mechanism, a filtering mechanism and a limiting mechanism, wherein the heat insulation mechanism is sleeved on the side wall of the pipeline; the fixing mechanism props against the pipeline and is arranged inside the heat preservation mechanism; the filter mechanism is arranged at one end of the pipeline and comprises a fixing ring, a connecting ring, a filter screen and a storage ball, the fixing ring is arranged in the pipeline, the filter screen in a round table shape is arranged at one end of the fixing ring, the connecting ring with an arc-shaped side wall is arranged in the filter screen at equal intervals, and the storage ball is arranged at one end of the filter screen; the limiting mechanism is arranged at the joint of the fixing ring and the pipeline.

Preferably, the heat preservation mechanism includes that protective sheath, first heat preservation are cotton and second heat preservation are cotton, the lateral wall suit of pipeline the second heat preservation is cotton, the cotton lateral wall suit of second heat preservation first heat preservation is cotton, just the cotton lateral wall installation of first heat preservation the protective sheath.

Preferably, the fixing mechanism comprises a hinge, a clamping plate and a fixing rod, two ends of the fixing rod respectively abut against the side wall of the protective sleeve and the side wall of the pipeline, the clamping plate is mounted on the side wall of the fixing rod, and the clamping plate abuts against the second heat-preservation cotton; the lateral wall installation of splint the hinge, and have elasticity the hinge is contradicted the second keeps warm cottonly.

Preferably, the fixing rod penetrates through the first heat-insulating cotton and the second heat-insulating cotton, and the fixing rod is installed on the side wall of the pipeline at equal intervals.

Preferably, the limiting mechanism comprises supporting blocks, rubber rings, a screw and fixing blocks, the supporting blocks are arranged in one end of the pipeline at equal intervals, and the fixing blocks are arranged on the side walls of the fixing rings at equal intervals; the supporting block and one end of the fixed block are respectively provided with the rubber ring, the supporting block and the inside of the fixed block are respectively in threaded connection with the screw rod, and the rubber ring is abutted against the fixed block or the screw rod.

Preferably, one end of the rubber ring is semicircular in cross section, and the inner diameter of the rubber ring is smaller than the maximum diameter of the screw.

Preferably, the diameter of the fixing ring is equal to the inner diameter of the pipe, and the diameter of the storage ball is greater than the minimum inner diameter of the filter screen.

Compared with the related art, the heat transmission energy-saving pipeline provided by the invention has the following beneficial effects:

the invention provides a heat transmission energy-saving pipeline, when hot water is transported in the pipeline, a filter screen is fixed in the pipeline by a fixing ring, the hot water penetrates through a hollow truncated cone-shaped filter screen and enters the central position in the pipeline, impurities in the hot water are left in the filter screen, the hot water moves in the filter screen, the hot water pushes the impurities to move in the filter screen, the filter screen is truncated cone-shaped, the impurities on the filter screen move to the central position in the filter screen from the edge of the side wall of the filter screen, the impurities are contacted with a connecting ring, the impurities slide through the connecting ring with the arc-shaped side wall at one end and move to the central position in the filter screen, when the impact force of the hot water is reduced, the other end of the connecting ring is abutted against the impurities, the impurities are left at the other end of the connecting ring, and the impurities are prevented from rolling downwards and being left at the connecting position in the pipeline, make impurity follow the inside of filter screen slides the entering store the inside of ball, reduce impurity on the filter screen avoids impurity to block up the filter screen.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of a thermal transmission energy-saving pipeline provided by the present invention;

FIG. 2 is a cross-sectional view of the pipe structure shown in FIG. 1;

fig. 3 is a schematic view of the internal structure of the filter mechanism shown in fig. 2.

Reference numbers in the figures: 1. pipeline, 2, heat preservation mechanism, 21, protective sheath, 22, first heat preservation cotton, 23, second heat preservation cotton, 3, fixed establishment, 31, hinge, 32, splint, 33, dead lever, 4, stop gear, 41, supporting shoe, 42, rubber ring, 43, screw rod, 44, fixed block, 5, filter mechanism, 51, solid fixed ring, 52, go-between, 53, filter screen, 54, storage ball.

Detailed Description

The invention is further described with reference to the following figures and embodiments.

Please refer to fig. 1, fig. 2 and fig. 3 in combination, wherein fig. 1 is a schematic structural diagram of a preferred embodiment of the thermal transmission energy-saving pipeline provided in the present invention; FIG. 2 is a cross-sectional view of the pipe structure shown in FIG. 1; fig. 3 is a schematic view of the internal structure of the filter mechanism shown in fig. 2. The heat transmission energy-saving pipeline comprises: the device comprises a pipeline 1, a heat preservation mechanism 2, a fixing mechanism 3, a filtering mechanism 5 and a limiting mechanism 4, wherein the heat preservation mechanism 2 is sleeved on the side wall of the pipeline 1;

in a specific implementation process, the fixing mechanism 3 abuts against the pipeline 1, and the fixing mechanism 3 is installed inside the heat preservation mechanism 2; the filtering mechanism 5 is installed at one end of the pipeline 1, the filtering mechanism 5 comprises a fixing ring 51, a connecting ring 52, a filter screen 53 and a storage ball 54, the fixing ring 51 is installed inside the pipeline 1, the filter screen 53 in a truncated cone shape is installed at one end of the fixing ring 51, the connecting ring 52 with an arc-shaped side wall is installed inside the filter screen 53 at equal intervals, and the storage ball 54 is installed at one end of the filter screen 53; the limiting mechanism 4 is arranged at the joint of the fixing ring 51 and the pipeline 1.

In the specific implementation process, the heat preservation mechanism 2 includes a protective sleeve 21, first heat preservation cotton 22 and second heat preservation cotton 23, the lateral wall suit of pipeline 1 the second heat preservation cotton 23, the lateral wall suit of second heat preservation cotton 23 the first heat preservation cotton 22, just the lateral wall installation of first heat preservation cotton 22 the protective sleeve 21, for convenient use the protective sleeve 21 will first heat preservation cotton 22 and the second heat preservation cotton 23 are fixed the lateral wall of pipeline 1, make first heat preservation cotton 22 with the second heat preservation cotton 23 keep the inside temperature of pipeline 1, avoid a large amount of temperatures from the inside of pipeline 1 runs off.

In a specific implementation process, the fixing mechanism 3 includes a hinge 31, a clamping plate 32 and a fixing rod 33, two ends of the fixing rod 33 respectively abut against the side wall of the protective sleeve 21 and the side wall of the pipeline 1, the clamping plate 32 is installed on the side wall of the fixing rod 33, and the clamping plate 32 abuts against the second heat-insulating cotton 23; the lateral wall installation of splint 32 hinge 31, and have elasticity hinge 31 contradicts the cotton 23 of second heat preservation, for the convenience dead lever 33 is fixed splint 32 makes splint 32 extrudees the cotton 23 of second heat preservation, just the inflation in the 1 transportation of pipeline, the 1 extrusion of pipeline the cotton 23 of second heat preservation, the cotton 23 extrusion of second heat preservation hinge 31 makes hinge 31 lengthens, thereby makes hinge 31 tightly ties up the cotton 23 of second heat preservation, makes the cotton 23 of second heat preservation is hugged closely the lateral wall of pipeline 1.

In the specific implementation process, the fixing rod 33 penetrates through the first heat preservation cotton 22 and the second heat preservation cotton 23, the fixing rod 33 is installed on the side wall of the pipeline 1 at the equal distance, and in order to facilitate the fixing of the fixing rod 33 on the first heat preservation cotton 22 and the second heat preservation cotton 23, the pipeline 1 is wrapped by the first heat preservation cotton 22 and the second heat preservation cotton 23.

In a specific implementation process, the limiting mechanism 4 comprises a supporting block 41, a rubber ring 42, a screw 43 and a fixing block 44, the supporting block 41 is installed inside one end of the pipeline 1 at equal intervals, and the fixing block 44 is installed on the side wall of the fixing ring 51 at equal intervals; the rubber rings 42 are respectively installed at one ends of the supporting block 41 and the fixed block 44, the interiors of the supporting block 41 and the fixed block 44 are respectively in threaded connection with the screw 43, the rubber rings 42 abut against the fixed block 44 or the screw 43, in order to facilitate sliding of the fixed ring 51, the fixed ring 51 is made to slide in the pipeline 1 and contact with the supporting block 41, the screw 43 is used to enable the screw 43 to penetrate through the fixed block 44 and the supporting block 41, and the screw 43 fixes the fixed block 44 and the supporting block 41 together, so that the fixed ring 51 is fixed in the pipeline 1.

In a specific implementation process, a cross section of one end of the rubber ring 42 is semicircular, and an inner diameter of the rubber ring 42 is smaller than a maximum diameter of the screw 43, so that the rubber ring 42 is tightly attached to the screw 43 and the supporting block 41, the rubber ring 42 seals a connection part between the screw 43 and the supporting block 41 and a gap between the screw 43 and the fixed block 44, and the screw 43 is prevented from rusting inside the fixed block 44 and the supporting block 41.

In a specific implementation process, the diameter of the fixing ring 51 is equal to the inner diameter of the pipeline 1, and the diameter of the storage ball 54 is larger than the minimum inner diameter of the filter screen 53, so that impurities are conveniently left in the storage ball 54, and the impurities are prevented from sliding out of the storage ball 54.

The working principle of the thermal transmission energy-saving pipeline provided by the invention is as follows: the fixing ring 51 is slid to make the fixing ring 51 bring the filter screen 53 into the interior of the pipeline 1, the fixing ring 51 slides inside the pipe 1 to contact the supporting block 41, the screw 43 is used to penetrate the fixing block 44 and the supporting block 41, one end of the fixing block 44 presses the rubber ring 42 at one end of the supporting block 41, the screw 43 fixes the fixing block 44 and the supporting block 41 together, thereby fixing the fixing ring 51 inside the pipeline 1, and the inner diameter of the rubber ring 42 is smaller than the maximum diameter of the screw 43, so that the rubber ring 42 is tightly attached to the screw 43 and the supporting block 41, and the rubber ring 42 seals the connection between the screw 43 and the supporting block 41 and the gap between the screw 43 and the fixing block 44, and prevents the screw 43 from rusting inside the fixing block 44 and the supporting block 41. Will pipeline 1 splices each other, makes pipeline 1 transports geothermal water, and geothermal water is in when pipeline 1's inside flows, dead lever 33 is fixed splint 32 makes splint 32 extrudees the second heat preservation cotton 23, just the inflation in the pipeline 1 transportation, pipeline 1 extrudees the second heat preservation cotton 23, the second heat preservation cotton 23 extrudees hinge 31 makes hinge 31 elongates, thereby makes hinge 31 tightly ties up the second heat preservation cotton 23, makes the second heat preservation cotton 23 hug closely the lateral wall of pipeline 1, just protective sheath 21 will first heat preservation cotton 22 with the second heat preservation cotton 23 is fixed the lateral wall of pipeline 1 makes first heat preservation cotton 22 with the second heat preservation cotton 23 keeps the inside temperature of pipeline 1 avoids a large amount of temperatures from the inside of pipeline 1 runs off. When geothermal water is in the inside of pipeline 1 flows, the hot water runs through hollow round platform shape the filter screen 53 gets into the inside department placed in the middle of pipeline 1, the inside impurity of hot water is stayed in the inside of filter screen 53, and hot water is in the inside motion of filter screen 53, hot water promotes impurity and is in the inside motion of filter screen 53, filter screen 53 is round platform shape, makes impurity on the filter screen 53 move to the inside department placed in the middle of filter screen 53 from the lateral wall edge of filter screen 53, impurity with go-between 52 contact, impurity is curved at one end lateral wall go-between 52 slide continue to the inside department placed in the middle of filter screen 53 removes, and when hot water impulsive force reduces, the other end of go-between 52 contradicts impurity, stays impurity the other end of go-between 52, avoids impurity to roll downwards and stays the inside junction of pipeline 1, makes impurity slide from the inside of filter screen 53 and gets into the inside of storage ball 54, the diameter of the storage ball 54 is larger than the minimum inner diameter of the filter screen 53, so that impurities are prevented from sliding out of the storage ball 54 in order to leave the impurities in the storage ball 54, the impurities on the filter screen 53 are reduced, the filter screen 53 is prevented from being blocked by the impurities, and hot water can flow in the pipeline 1 conveniently.

the invention provides a heat transmission energy-saving pipeline, when hot water is transported in the pipeline 1, a fixing ring 51 fixes a filter screen 53 in the pipeline 1, the hot water penetrates through a hollow truncated cone-shaped filter screen 53 and enters the central position in the pipeline 1, impurities in the hot water are left in the filter screen 53, the hot water moves in the filter screen 53, the hot water pushes the impurities to move in the filter screen 53, the filter screen 53 is in a truncated cone shape, the impurities on the filter screen 53 move to the central position in the filter screen 53 from the side wall edge of the filter screen 53, the impurities are contacted with a connecting ring 52, the impurities slide through the connecting ring 52 with the side wall of one end being arc-shaped and move continuously to the central position in the filter screen 53, and when the impact force of the hot water is reduced, the other end of the connecting ring 52 is abutted against the impurities, the impurities are left at the other end of the connecting ring 52, avoid impurity to roll down and stay the inside junction of pipeline 1 makes impurity follow the inside of filter screen 53 slides and gets into store the inside of ball 54, reduces impurity on the filter screen 53 avoids impurity to block up filter screen 53 makes things convenient for hot water to be in the inside of pipeline 1 flows.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A heat transfer energy saving pipeline, comprising:

a conduit (1);

the heat preservation mechanism (2) is sleeved on the side wall of the pipeline (1), the heat preservation mechanism (2) comprises a protective sleeve (21), first heat preservation cotton (22) and second heat preservation cotton (23), the second heat preservation cotton (23) is sleeved on the side wall of the pipeline (1), the first heat preservation cotton (22) is sleeved on the side wall of the second heat preservation cotton (23), and the protective sleeve (21) is installed on the side wall of the first heat preservation cotton (22);

the fixing mechanism (3) is abutted against the pipeline (1), the fixing mechanism (3) is installed inside the heat preservation mechanism (2), the fixing mechanism (3) comprises a hinge (31), a clamping plate (32) and a fixing rod (33), two ends of the fixing rod (33) are respectively abutted against the side wall of the protective sleeve (21) and the side wall of the pipeline (1), the clamping plate (32) is installed on the side wall of the fixing rod (33), and the clamping plate (32) is abutted against the second heat preservation cotton (23); the hinge (31) is installed on the side wall of the clamping plate (32), the hinge (31) with elasticity props against the second heat-preservation cotton (23), the fixing rod (33) penetrates through the first heat-preservation cotton (22) and the second heat-preservation cotton (23), and the fixing rod (33) is installed on the side wall of the pipeline (1) at equal intervals;

the filter mechanism (5), the filter mechanism (5) is installed at one end of the pipeline (1), the filter mechanism (5) comprises a fixing ring (51), a connecting ring (52), a filter screen (53) and a storage ball (54), the fixing ring (51) is installed inside the pipeline (1), the filter screen (53) in a round table shape is installed at one end of the fixing ring (51), the connecting ring (52) with a plurality of side walls in an arc-shaped structure is installed inside the filter screen (53) at equal intervals, the storage ball (54) is installed at one end of the filter screen (53), the diameter of the fixing ring (51) is equal to the inner diameter of the pipeline (1), and the diameter of the storage ball (54) is larger than the minimum inner diameter of the filter screen (53);

the limiting mechanism (4) is installed at the connecting position of the fixing ring (51) and the pipeline (1), the limiting mechanism (4) comprises a supporting block (41), a rubber ring (42), a screw (43) and a fixing block (44), the supporting block (41) is installed inside one end of the pipeline (1) at equal intervals, and the fixing block (44) is installed on the side wall of the fixing ring (51) at equal intervals; the rubber ring (42) is respectively installed at one end of the supporting block (41) and one end of the fixing block (44), the supporting block (41) and the fixing block (44) are respectively in threaded connection with the screw rod (43), the rubber ring (42) abuts against the fixing block (44) or the screw rod (43), the cross section of one end of the rubber ring (42) is semicircular, and the inner diameter of the rubber ring (42) is smaller than the maximum diameter of the screw rod (43).