CN111911723A

CN111911723A - Magnetic traction type tap water pipe orifice ice resistance resisting flange ring

Info

Publication number: CN111911723A
Application number: CN202010643482.8A
Authority: CN
Inventors: 周兴龙
Original assignee: 周兴龙
Current assignee: Shandong SHUNFA Heavy Industry Co.,Ltd.
Priority date: 2020-07-07
Filing date: 2020-07-07
Publication date: 2020-11-10
Anticipated expiration: 2040-07-07
Also published as: CN111911723B

Abstract

The invention discloses a magnetic traction type tap water pipe orifice anti-ice-resistance flange ring, which belongs to the technical field of water pipes, and the scheme is characterized in that a magnet disc is overturned and attracts an annular magnet block by virtue of the magnet disc, a sealing plug is taken out from a first release hole, an outer traction ring is rotated so as to pull the annular magnet block to rotate in an inner annular frame, a scraping layer of the scraped part is pushed out from the first release hole, so that the scraping layer is contacted with ice in the inner annular wall of the inner annular frame to force the ice to melt, partial calcium oxide powder can be generated by virtue of mutual friction between a grinding ball and the scraping layer, and the calcium oxide powder reacts and emits a large amount of heat when the scraping layer is contacted with melted water, so that the melting of the ice can be accelerated, when a sealing plug moves upwards, less ice can be taken into the inner annular frame by virtue of a receiving groove and a picking rope in the sealing plug, the ice reacts with the grinding ball after melting, the temperature in the inner annular frame, thereby improving the efficiency of melting the ice blocks in the inner ring wall of the built-in annular frame.

Description

Magnetic traction type tap water pipe orifice ice resistance resisting flange ring

Technical Field

The invention relates to the technical field of water pipes, in particular to a magnetic traction type anti-ice-resistance flange ring of a tap water pipe opening.

Background

The tap water is water which is purified and disinfected by a tap water treatment plant and is produced by the tap water treatment plant and meets the corresponding standard for life and production of people. The domestic water mainly draws rivers, lakes, underground water and surface water through a water intake pump station of a water plant, is treated by the process flows of precipitation, disinfection, filtration and the like according to the national sanitary standards for drinking water for life by the water plant, and is finally conveyed to each user through a water distribution pump station.

The water pipe is a water supply pipeline, modern decoration water pipes are constructed in a wall-buried mode, the water pipes are classified into three types, and the first type is a metal pipe, such as a hot-dip cast iron pipe with inner enamel plastics, a copper pipe, a stainless steel pipe and the like. The second type is plastic-clad metal pipes, such as plastic-clad steel pipes, aluminum-plastic composite pipes and the like. The third category is plastic pipes, such as PB, PP-R, etc., and in the past, the pipes used for water supply were mainly cast iron pipes. The sand mould cast iron pipe is mainly used outdoors, and the galvanized cast iron pipe is used indoors. But after being used for several years, a large amount of rust scale is easy to generate, bacteria are bred, and the health of a human body is seriously harmed. The state has stipulated that sand mould casting pipe fittings and cold galvanized cast iron pipes are eliminated from 2000, 6, 1, month, the use of hot galvanized cast iron pipes is gradually limited, and aluminum plastic composite pipes, novel plastic pipes and the like are popularized and used.

At present, when the tap water pipeline is used in winter, the phenomenon of icing of water in the pipeline is easy to occur, so that the tap water is influenced to be used by people.

Disclosure of Invention

1. Technical problem to be solved

Aiming at the problems in the prior art, the invention aims to provide a magnetic traction type tap water pipe orifice anti-ice-resistance flange ring, the scheme is that a magnet disc is overturned and attracts an annular magnet block by virtue of the magnet disc, a sealing plug is taken out from a first release hole, an outer traction ring is rotated so as to pull the annular magnet block to rotate in an inner annular frame, a scraping layer of the scraped part is pushed out from the first release hole, so that the scraping layer is in contact with ice on the inner annular wall of the inner annular frame to force the ice to melt, partial calcium oxide powder can be generated by virtue of mutual friction between a grinding ball and the scraping layer, and reacts and emits a large amount of heat when the scraping layer is in contact with melted water, the melting of the ice can be accelerated, when the sealing plug moves upwards, less ice can be taken into the inner annular frame by virtue of a receiving groove and a picking rope in the sealing plug, and the ice reacts with the grinding ball after being melted, the temperature in the built-in annular frame can be increased, and therefore the efficiency of melting ice blocks in the inner annular wall of the built-in annular frame is improved.

2. Technical scheme

In order to solve the above problems, the present invention adopts the following technical solutions.

A magnetic traction type tap water pipe orifice anti-ice-resistance flange ring comprises a water pipe and a faucet, wherein a flange ring is in threaded connection between the water pipe and the faucet, the outer end of the flange ring is rotatably connected with an outer traction ring, the upper end of the outer traction ring is fixedly connected with a rotary grab handle, the upper end of the rotary grab handle is in threaded connection with a magnet disc, the inner wall of the outer traction ring is fixedly connected with a built-in annular frame, a first release hole is formed in the inner annular wall of the built-in annular frame, a sealing plug is inserted into the first release hole, the upper end of the sealing plug is fixedly connected with an annular magnet block positioned in the built-in annular frame, a scraping layer is fixedly connected with the inner wall of the built-in annular frame, a plurality of grinding balls which are uniformly distributed are arranged in the built-in annular frame, the magnet disc is overturned to enable the, the outer traction ring is rotated to pull the annular magnet block to rotate in the built-in annular frame, the scraping layer is scraped by the sealing plug, the grinding balls are pushed to rotate in the built-in annular frame, the scraped part of the scraping layer is pushed out of the first release holes after the scraping layer rotates for a circle, the scraping layer is contacted with ice between the inner annular wall of the built-in annular frame to force the ice to melt, meanwhile, by means of mutual friction between the grinding balls and the scraping layer, partial calcium oxide powder can be generated, and the calcium oxide powder reacts and emits a large amount of heat when contacting melted water, so that melting of the ice can be accelerated.

Furthermore, a plurality of uniformly distributed accommodating grooves are formed in the bottom end of the sealing plug, a pickup rope is fixedly connected to the inner bottom end of each accommodating groove and comprises a memory alloy cladding, an elastic film is fixedly connected to the inner wall of each memory alloy cladding, magnetic fluid is filled in each elastic film, a plurality of uniformly distributed capillary fiber spines are fixedly connected to the outer end of each memory alloy cladding, when the sealing plug moves upwards, less ice can be brought into the built-in annular frame by means of the accommodating grooves and the pickup ropes in the sealing plug, the magnetic fluid can be pulled to move upwards by means of the adsorption effect of the annular magnet blocks on the magnetic fluid, so that the memory alloy cladding is gradually thickened from bottom to top, the possibility that the ice falls from the accommodating grooves when the sealing plug moves upwards is reduced, and meanwhile, the ice can be accelerated to melt in the built-in annular frame along with the continuous friction of the sealing plug and the scraping layer, on the other hand, the temperature of the memory alloy cladding can be increased, so that the memory alloy cladding deforms to a high-temperature phase state to accelerate the fragmentation of ice blocks outside the memory alloy cladding, the melting rate of the ice blocks is further improved, the ice blocks react with the grinding balls after melting, the temperature in the built-in annular frame can be increased, and the melting efficiency of the ice blocks in the inner annular wall of the built-in annular frame is improved.

Further, built-in annular frame inner wall fixedly connected with is located the arc storage bag in the annular magnet piece outside, arc storage bag intussuseption is filled with heat preservation lubricating oil, arc storage bag opens the chisel in the outer end and has the second release hole that is located first release hole upside, second release hole inner wall fixedly connected with a pair of rubber mounting that supports tightly each other, through setting up arc storage bag and heat preservation lubricating oil, can extrude arc storage bag at annular magnet piece pivoted in-process to force heat preservation lubricating oil to push open blowout behind the second release hole, can reduce the sealing plug and built-in annular frame wearing and tearing excessively and the possibility of damaging on the one hand, on the other hand can reduce the possibility that the inside temperature of built-in annular frame scatters and disappears fast with the help of the heat preservation effect of heat preservation lubricating oil.

Furthermore, a plurality of spherical grooves which are uniformly distributed are formed in the inner wall of the outer traction ring, balls are rotatably connected in the spherical grooves, and the possibility of blocking of the outer traction ring in the rotating process can be reduced by arranging the spherical grooves and the balls.

Furthermore, the outer end of the rotary grab handle is provided with a pair of hemispherical cylindrical grooves which are symmetrical relative to the magnet disc, the inner wall of each hemispherical cylindrical groove is carved with anti-skidding grains, the outer traction ring can be conveniently rotated by arranging the hemispherical cylindrical grooves and arranging the anti-skidding grains on the inner wall of the hemispherical cylindrical grooves, and the possibility that the hands of technicians slip when contacting the hemispherical cylindrical grooves is reduced.

Further, the scraping layer is formed by polymerizing sodium chloride powder, the grinding balls are formed by polymerizing calcium oxide powder, the scraping layer is manufactured by using the sodium chloride powder, ice blocks can be melted by means of the property that the freezing point of water can be lowered by means of the sodium chloride, and the grinding balls are manufactured by using the calcium oxide powder, so that the ice melting can be further accelerated by means of the property that the calcium oxide powder and the water are combined to release heat.

Furthermore, the memory alloy cladding is made of Ni-Ti memory alloy materials, the transformation temperature of the memory alloy cladding is 40 ℃, and the memory alloy cladding made of the Ni-Ti memory alloy materials can enable the memory alloy cladding to have the property of easy deformation at low temperature and recover the high-temperature phase state after the temperature rises.

Furthermore, the heat-preservation lubricating oil is prepared from soybean oil, the melting point of the heat-preservation lubricating oil is-15 ℃, and the possibility of freezing of the heat-preservation lubricating oil due to too low temperature when water is frozen can be reduced by using the soybean oil to prepare the heat-preservation lubricating oil, so that the heat-preservation lubricating oil is convenient to release.

A use method of a magnetic traction type tap water pipe orifice anti-ice-resistance flange ring comprises the following steps:

s1, the sealing plug is taken out from the first release hole by turning over the magnet disc and attracting the annular magnet block by the magnet disc, the outer traction ring is rotated to draw the annular magnet block to rotate in the built-in annular frame, and the scraped part of the scraping layer is pushed out from the first release hole and is contacted with ice between the scraping layer and the inner annular wall of the built-in annular frame to force the ice to melt;

s2, partial calcium oxide powder can be generated by means of mutual friction between the grinding balls and the wiping layer, and the calcium oxide powder reacts and emits a large amount of heat when contacting with melted water, so that melting of ice can be accelerated;

s3, when the sealing plug moves upwards, less ice can be brought into the built-in annular frame by the aid of the containing groove and the picking rope in the sealing plug, the ice reacts with the grinding balls after melting, the temperature in the built-in annular frame can be increased, and accordingly the efficiency of melting ice blocks in the inner annular wall of the built-in annular frame is improved.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) the scheme takes the sealing plug out of the first release hole by turning over the magnet disc and attracting the annular magnet block by the magnet disc, the outer traction ring is rotated to draw the annular magnet block to rotate in the built-in annular frame, the scraped part of the scraping layer is pushed out from the first release hole to be in contact with ice between the inner annular wall of the built-in annular frame to force the ice to melt, and the grinding balls and the scraping layer rub against each other, can generate partial calcium oxide powder, react and emit a large amount of heat when contacting with melted water, can accelerate the melting of ice, when the sealing plug moves upwards, less ice can be brought into the built-in annular frame by virtue of the containing groove and the picking rope in the sealing plug, the ice reacts with the grinding ball after melting, the temperature in the built-in annular frame can be increased, and therefore the efficiency of melting ice blocks in the inner annular wall of the built-in annular frame is improved.

(2) The bottom end of the sealing plug is provided with a plurality of uniformly distributed accommodating grooves, the inner bottom end of each accommodating groove is fixedly connected with a pickup rope, each pickup rope comprises a memory alloy cladding, the inner wall of each memory alloy cladding is fixedly connected with an elastic film, each elastic film is filled with magnetic fluid, the outer end of each memory alloy cladding is fixedly connected with a plurality of uniformly distributed capillary fiber spines, when the sealing plug moves upwards, fewer ice can be brought into the built-in annular frame by virtue of the accommodating grooves and the pickup ropes in the sealing plug, the magnetic fluid can be pulled to move upwards by virtue of the adsorption effect of the annular magnet blocks on the magnetic fluid, so that the memory alloy cladding is gradually thickened from bottom to top, the possibility that the ice falls from the accommodating grooves when the sealing plug moves upwards is reduced, meanwhile, along with continuous friction with the scraping layer, on one hand, the melting of the ice in the built-in annular frame can be accelerated, therefore, the ice blocks outside the built-in annular frame can be accelerated to be broken when the ice blocks are deformed to the high-temperature phase state, the melting rate of the ice blocks is further improved, the ice blocks are reacted with the grinding balls after being melted, the temperature in the built-in annular frame can be increased, and the melting efficiency of the ice blocks in the inner annular wall of the built-in annular frame is improved.

(3) Built-in annular frame inner wall fixedly connected with is located the arc storage bag in the annular magnet piece outside, arc storage bag intussuseption is filled with heat preservation lubricating oil, the second release hole that is located first release hole upside is dug to arc storage bag outer end, a pair of mutual tight rubber mounting of second release hole inner wall fixedly connected with, through setting up arc storage bag and heat preservation lubricating oil, can extrude arc storage bag at annular magnet piece pivoted in-process, thereby force heat preservation lubricating oil to push open blowout behind the second release hole, can reduce the sealing plug and built-in annular frame wearing and tearing excessively and the possibility of damaging on the one hand, on the other hand can be with the help of the heat preservation effect of heat preservation lubricating oil, reduce the inside quick lost possibility of temperature of built-in annular frame.

(4) The inner wall of the outer traction ring is provided with a plurality of uniformly distributed spherical grooves in a chiseled mode, the spherical grooves are connected with balls in a rotating mode, and the possibility that the outer traction ring is blocked in the rotating process can be reduced by arranging the spherical grooves and the balls.

(5) The outer end of the rotary grab handle is provided with a pair of hemispherical cylindrical grooves which are symmetrical relative to the magnet disc, the inner walls of the hemispherical cylindrical grooves are carved with anti-skid grains, the outer traction ring can be conveniently rotated by arranging the hemispherical cylindrical grooves and arranging the anti-skid grains on the inner walls of the hemispherical cylindrical grooves, and the possibility that the hands of technicians slip when contacting the hemispherical cylindrical grooves is reduced.

(6) The scraping layer is formed by polymerizing sodium chloride powder, the grinding balls are formed by polymerizing calcium oxide powder, the scraping layer is manufactured by using the sodium chloride powder, ice blocks can be melted by means of the property that the freezing point of water can be lowered by means of the sodium chloride, and the ice melting can be further accelerated by means of the property that the calcium oxide powder is combined with the water to release heat by means of the property that the calcium oxide powder is used for manufacturing the grinding balls.

(7) The memory alloy cladding is made of Ni-Ti memory alloy materials, the transformation temperature of the memory alloy cladding is 40 ℃, and the memory alloy cladding is made of the Ni-Ti memory alloy materials, so that the memory alloy cladding has the property of easy deformation at low temperature and can recover the high-temperature phase state after the temperature rises.

(8) The heat-preservation lubricating oil is prepared from soybean oil, the melting point of the heat-preservation lubricating oil is-15 ℃, and the possibility of solidification of the heat-preservation lubricating oil due to too low temperature when water is frozen can be reduced by using the soybean oil to prepare the heat-preservation lubricating oil, so that the heat-preservation lubricating oil is convenient to release.

Drawings

FIG. 1 is a cross-sectional view of the junction of a water conduit and a faucet of the present invention;

FIG. 2 is a cross-sectional view of a flange ring portion of the present invention;

FIG. 3 is a schematic view of the structure at A in FIG. 2;

FIG. 4 is a cross-sectional view of the flange ring of the present invention in operation;

fig. 5 is a cross-sectional view of a portion of a pickup cord of the present invention.

The reference numbers in the figures illustrate:

the device comprises a water pipe 1, a water tap 2, a flange ring 3, an external traction ring 4, a rolling ball 401, a rotary grab handle 5, a hemispherical cylindrical groove 501, a magnet disc 6, a built-in annular frame 7, a first release hole 8, a sealing plug 9, an annular magnet block 10, a scraping layer 11, a grinding ball 12, a receiving groove 13, a picking rope 14, a memory alloy cladding 15, an elastic film 16, a magnetic fluid 17, a capillary fiber thorn 18, an arc storage bag 19, heat preservation lubricating oil 20, a second release hole 21 and a rubber sealing sheet 22.

Detailed Description

The drawings in the embodiments of the invention will be combined; the technical scheme in the embodiment of the invention is clearly and completely described; obviously; the described embodiments are only some of the embodiments of the invention; but not all embodiments, are based on the embodiments of the invention; all other embodiments obtained by a person skilled in the art without making any inventive step; all fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "sleeved/connected," "connected," and the like are to be construed broadly, e.g., "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

referring to fig. 1-4, a magnetic traction type tap water pipe orifice anti-ice-resistance flange ring comprises a water pipe 1 and a tap 2, a flange ring 3 is connected between the water pipe 1 and the tap 2 by screw threads, an outer traction ring 4 is rotatably connected at the outer end of the flange ring 3, a rotary grab handle 5 is fixedly connected at the upper end of the outer traction ring 4, a magnet disc 6 is connected at the upper end of the rotary grab handle 5 by screw threads, a built-in annular frame 7 is fixedly connected at the inner wall of the outer traction ring 4, a first release hole 8 is chiseled on the inner annular wall of the built-in annular frame 7, a sealing plug 9 is inserted in the first release hole 8, an annular magnet block 10 positioned in the built-in annular frame 7 is fixedly connected at the upper end of the sealing plug 9, a scraping layer 11 is fixedly connected at the inner wall of the built-in annular frame 7, a plurality of grinding balls 12 uniformly distributed are, thereby taking the sealing plug 9 out of the first release hole 8, rotating the outer traction ring 4 to draw the annular magnet block 10 to rotate in the built-in annular frame 7, scraping the scraping layer 11 by the sealing plug 9, simultaneously pushing the grinding ball 12 to rotate in the built-in annular frame 7, and after one rotation, pushing out the scraped part of the scraping layer 11 from the first release hole 8 to make the part of the scraping layer contact with the ice in the built-in annular frame 7 to force the ice to melt, and simultaneously generating part of the calcium oxide powder by mutual friction between the grinding ball 12 and the scraping layer 11, reacting and releasing a large amount of heat when the part of the scraping layer 11 contacts with the melted water, thereby accelerating the melting of the ice.

Referring to fig. 3-5, a plurality of uniformly distributed receiving grooves 13 are cut at the bottom end of the sealing plug 9, a picking rope 14 is fixedly connected to the inner bottom end of the receiving groove 13, the picking rope 14 includes a memory alloy cladding 15, an elastic film 16 is fixedly connected to the inner wall of the memory alloy cladding 15, a magnetic fluid 17 is filled in the elastic film 16, a plurality of uniformly distributed capillary fiber pricks 18 are fixedly connected to the outer end of the memory alloy cladding 15, when the sealing plug 9 moves upwards, less ice can be brought into the built-in annular frame 7 by means of the receiving grooves 13 and the picking rope 14 in the sealing plug 9, the magnetic fluid 17 can be pulled upwards by means of the adsorption effect of the annular magnet block 10 on the magnetic fluid 17, so that the memory alloy cladding 15 is gradually thickened from top to bottom, thereby reducing the possibility that ice falls from the receiving grooves 13 when the sealing plug 9 moves upwards, and meanwhile, the sealing plug 9 continuously rubs with the, on one hand, the melting of ice in the built-in annular frame 7 can be accelerated, on the other hand, the temperature of the memory alloy cladding 15 can be increased, so that the ice blocks outside the memory alloy cladding can be accelerated to be broken when the memory alloy cladding is deformed to the high-temperature phase state, the melting rate of the ice blocks is further increased, the ice blocks react with the grinding balls 12 after being melted, the temperature in the built-in annular frame 7 can be increased, and the melting efficiency of the ice blocks in the inner annular wall of the built-in annular frame 7 is improved.

Referring to fig. 3, an arc storage pocket 19 located outside the ring magnet block 10 is fixedly connected to an inner wall of the built-in ring frame 7, heat preservation lubricant 20 is filled in the arc storage pocket 19, a second release hole 21 located above the first release hole 8 is drilled at an outer end of the arc storage pocket 19, a pair of rubber sealing pieces 22 abutting against each other is fixedly connected to an inner wall of the second release hole 21, and the arc storage pocket 19 and the heat preservation lubricant 20 are arranged to extrude the arc storage pocket 19 in a rotating process of the ring magnet block 10, so that the heat preservation lubricant 20 is forced to eject out after pushing against the second release hole sealing plug 21, on one hand, the possibility that the built-in ring frame 7 is damaged due to excessive wear can be reduced, and on the other hand, the possibility that the internal temperature of the built-in ring frame 7 is rapidly dissipated can be reduced by virtue of a heat preservation.

Referring to fig. 2 and 4, the inner wall of the outer traction ring 4 is drilled with a plurality of spherical grooves which are uniformly distributed, the spherical grooves are rotatably connected with balls 401, the possibility of blocking of the outer traction ring 4 in the rotating process can be reduced by arranging the spherical grooves and the balls 401, the outer end of the rotating grab handle 5 is drilled with a pair of hemispherical cylindrical grooves 501 which are symmetrical relative to the magnet disc 6, the inner wall of the hemispherical cylindrical grooves 501 is carved with anti-slip patterns, the outer traction ring 4 can be conveniently rotated by arranging the hemispherical cylindrical grooves 501 and arranging the anti-slip patterns on the inner wall of the hemispherical cylindrical grooves, and the possibility of slipping when a hand of a technician contacts the hemispherical cylindrical grooves 501 is reduced.

Referring to fig. 3 and 5, the wiping layer 11 is formed by polymerizing sodium chloride powder, the grinding ball 12 is formed by polymerizing calcium oxide powder, the wiping layer 11 is formed by using the sodium chloride powder, ice cubes can be melted by using the property that the freezing point of water can be lowered by using the sodium chloride, the grinding ball 12 is formed by using the calcium oxide powder, the melting of ice can be further accelerated by using the property that the calcium oxide powder is combined with water to release heat, the memory alloy cladding 15 is made of a Ni-Ti memory alloy material, the transformation temperature of the memory alloy cladding 15 is 40 ℃, the memory alloy cladding 15 is formed by using the Ni-Ti memory alloy material, the memory alloy cladding 15 can have the property of easy deformation at a low temperature and can recover the high-temperature phase state after the temperature is raised, the heat-preserving lubricating oil 20 is made of soybean oil, the melting point of the heat-preserving lubricating oil 20 is-15 ℃, by using soybean oil to prepare the heat-preserving lubricating oil 20, the possibility that the heat-preserving lubricating oil 20 is solidified due to the fact that the temperature is too low when water is frozen can be reduced, and therefore the heat-preserving lubricating oil 20 is convenient to release.

s1, the sealing plug 9 is taken out from the first release hole 8 by turning over the magnet disc 6 and attracting the annular magnet block 10 by the magnet disc, the outer traction ring 4 is rotated to draw the annular magnet block 10 to rotate in the built-in annular frame 7, the scraped part of the scraping layer 11 is pushed out from the first release hole 8, and the scraping layer is contacted with the ice between the inner annular walls of the built-in annular frame 7 to force the ice to melt;

s2, by means of mutual friction between the grinding balls 12 and the wiping layer 11, partial calcium oxide powder can be generated and reacts and emits a large amount of heat when contacting with the melting water, which can accelerate melting of ice;

s3 and the sealing plug 9 move upwards, less ice can be brought into the built-in annular frame 7 through the containing groove 13 and the picking rope 14 in the sealing plug, the ice reacts with the grinding balls 12 after melting, the temperature in the built-in annular frame 7 can be increased, and accordingly the efficiency of melting ice blocks in the inner annular wall of the built-in annular frame 7 is improved.

The above; but are merely preferred embodiments of the invention; the scope of the invention is not limited thereto; any person skilled in the art is within the technical scope of the present disclosure; the technical scheme and the improved concept of the invention are equally replaced or changed; are intended to be covered by the scope of the present invention.

Claims

1. The utility model provides an anti ice resistance flange ring of magnetism towed running water pipe mouth, includes conduit (1) and tap (2), threaded connection has flange ring (3), its characterized in that between conduit (1) and tap (2): the utility model discloses a take-up device, including flange ring (3), outer traction ring (4) are connected with in the rotation of flange ring (3) outer end, outer traction ring (4) upper end fixedly connected with rotates grab handle (5), it has magnet disc (6) to rotate grab handle (5) upper end threaded connection, outer traction ring (4) inner wall fixedly connected with embeds annular frame (7), the inner ring wall chisel in embeds annular frame (7) has first release hole (8), first release hole (8) interpolation is equipped with sealing plug (9), sealing plug (9) upper end fixedly connected with is located annular magnet piece (10) of embedding annular frame (7), layer (11) are wiped away to built-in annular frame (7) inner wall fixedly connected with, be equipped with a plurality of evenly distributed's grinding ball (12) in built-in annular frame (7).

2. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 1, wherein: the bottom end of the sealing plug (9) is provided with a plurality of uniformly distributed accommodating grooves (13), an inner bottom end of each accommodating groove (13) is fixedly connected with a pickup rope (14), each pickup rope (14) comprises a memory alloy cladding (15), an inner wall of each memory alloy cladding (15) is fixedly connected with an elastic film (16), each elastic film (16) is filled with a magnetic fluid (17), and an outer end of each memory alloy cladding (15) is fixedly connected with a plurality of uniformly distributed capillary fiber spines (18).

3. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 1, wherein: the built-in annular frame (7) inner wall fixedly connected with is located arc storage bag (19) in annular magnet piece (10) outside, arc storage bag (19) intussuseption is filled with heat preservation lubricating oil (20), second release hole (21) that are located first release hole (8) upside are dug to arc storage bag (19) outer end, second release hole (21) inner wall fixedly connected with a pair of rubber mounting (22) that support each other tightly.

4. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 1, wherein: the inner wall of the outer traction ring (4) is provided with a plurality of uniformly distributed spherical grooves, and the spherical grooves are connected with balls (401) in a rotating mode.

5. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 1, wherein: the outer end of the rotary grab handle (5) is provided with a pair of hemispherical cylindrical grooves (501) which are symmetrical relative to the magnet disc (6), and the inner walls of the hemispherical cylindrical grooves (501) are carved with anti-skid grains.

6. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 1, wherein: the scraping layer (11) is formed by polymerizing sodium chloride powder, and the grinding balls (12) are formed by polymerizing calcium oxide powder.

7. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 2, wherein: the memory alloy cladding (15) is made of Ni-Ti memory alloy materials, and the transformation temperature of the memory alloy cladding (15) is 40 ℃.

8. The magnetic traction type tap water pipe orifice ice resistance flange ring as claimed in claim 3, wherein: the heat-preservation lubricating oil (20) is prepared from soybean oil, and the melting point of the heat-preservation lubricating oil (20) is-15 ℃.

9. The use method of the magnetic traction type tap water pipe orifice anti-ice-resistance flange ring according to any one of claims 1 to 8, is characterized in that: the method comprises the following steps:

s1, the sealing plug (9) is taken out from the first release hole (8) by turning over the magnet disc (6) and attracting the annular magnet block (10) by the magnet disc, the outer traction ring (4) is rotated to draw the annular magnet block (10) to rotate in the built-in annular frame (7), the scraped part of the scraping layer (11) is pushed out from the first release hole (8), and the scraping layer is contacted with ice between the inner ring wall of the built-in annular frame (7) to force the ice to melt;

s2, partial calcium oxide powder can be generated by means of mutual friction between the grinding balls (12) and the wiping layer (11), and the calcium oxide powder reacts and emits a large amount of heat when contacting with melted water, so that melting of ice can be accelerated;

s3, when the sealing plug (9) moves upwards, less ice can be brought into the built-in annular frame (7) through the containing groove (13) and the picking rope (14) in the sealing plug, the ice reacts with the grinding ball (12) after melting, the temperature in the built-in annular frame (7) can be increased, and therefore the efficiency of melting ice blocks in the inner annular wall of the built-in annular frame (7) is improved.