CN220433581U - Microbubble ice melting device near pile pier and pier - Google Patents

Abstract

The utility model provides a microbubble ice melting device near a pile pier and a pier. Comprising the following steps: the floating assembly is connected to the pile pier and the pier and can float nearby the pile pier and the pier; the micro-bubble assembly is connected to the floating assembly, and each micro-bubble assembly is provided with a plurality of micro-air holes. The microbubble ice melting device near the pile pier and the pier solves the defect that existing ice melting equipment cannot melt ice in the vicinity of a circular building such as the pile pier and the pier in a targeted manner.

Description

Microbubble ice melting device near pile pier and pier

Technical Field

The utility model relates to the technical field of ice melting, in particular to a microbubble ice melting device near a pile pier and a pier.

Background

After the circular buildings such as the pile piers and the bridge piers are frozen with the ice layer, the hydraulic structure is subjected to compressive stress, lifting force or pulling force and other loads generated by ice pressure, ice bending moment and water level change, when the loads are repeatedly applied, the hydraulic structure is possibly deformed or damaged, and freezing and thawing damage can occur when water body permeates into the concrete, so that thawing of ice near the circular buildings such as the pile piers and the bridge piers in winter in the north becomes an important work for guaranteeing safe operation of hydraulic engineering, and therefore, the ice thawing equipment is required to eliminate freezing damage of the hydraulic equipment such as the pile piers and the bridge piers, and the like for the circular buildings; the pressurized water jet method can meet the ice melting requirement, but a single water pump has limited influence range, usually needs a plurality of water pumps to operate in a combined way, has high power, is inconvenient to install and disassemble, has high failure rate and has certain requirement on water depth, and is easy to freeze when the water is jetted onto a pile pier, a pier and the like which are round buildings; the electric heating method has a quick ice melting effect, is suitable for small-range ice melting scenes, is easy to generate electric leakage danger and has high energy consumption, and obviously, the three ice melting devices cannot melt ice in the vicinity of circular buildings such as piers and piers.

In summary, the existing ice melting equipment has the defect that ice melting can not be performed on the vicinity of a circular building such as a pier, a pier and the like in a targeted manner.

Disclosure of Invention

In order to solve the problems, the utility model provides a microbubble ice melting device near a pile pier and a pier, so as to solve the problems of the prior art.

According to a first aspect of the present utility model, there is provided a microbubble deicing device in the vicinity of a pier or pier, comprising: the floating assembly is connected to the pile pier and the pier and can float nearby the pile pier and the pier;

the micro-bubble assembly is connected to the floating assembly, and each micro-bubble assembly is provided with a plurality of micro-air holes.

Optionally, the method further comprises: each micro-bubble component is connected to the floating component through the corresponding connecting piece, and the micro-bubble components are uniformly arranged near the pile pier and the pier.

Optionally, the detachable suit of floating subassembly is on mound, pier, and a plurality of microbubble subassemblies regard the axis of mound, pier as the centre of a circle evenly to be arranged near mound, pier.

Optionally, the microbubble assembly comprises a microbubble support and a microbubble tube;

the microbubble support is detachably connected with the microbubble pipe, and a plurality of micro-air holes are formed in the microbubble pipe.

Alternatively, the micro air cells are shaped to extend from the middle portion to both ends, and become larger in size.

Optionally, the method further comprises: the fixing piece is detachably connected between the microbubble support piece and the microbubble tube, and the microbubble tube is positioned above the microbubble support piece.

Optionally, the shapes of the microbubble components are circular arcs, and the microbubble components are combined and surrounded to form a circular structure.

Optionally, the number of the microbubble components is 4-8.

Optionally, the method further comprises: the air supply assembly is detachably connected with the microbubble assemblies respectively, and the air supply assembly is communicated with the interiors of the microbubble assemblies.

Optionally, a connecting joint is arranged on the micro bubble tube, and the micro bubble tube is connected with the air supply assembly through the connecting joint.

The microbubble ice melting device near the pile pier and the pier is connected to the pile pier and the pier through the floating assembly, and the floating assembly can float near the pile pier and the pier; the micro-bubble assemblies are connected to the floating assembly, and each micro-bubble assembly is provided with a plurality of micro-air holes; the floating assembly floats on a water layer near the pile pier and the pier, the micro-bubble assembly is positioned in water, air flows out through a plurality of micro-bubble holes, a large amount of micro-bubbles are released into the water, the gas content in the water is rapidly and effectively increased, the water is pushed to move, the micro-bubbles are small in size and buoyancy, the residence time in the water is long, the ascending speed is slow, the micro-bubbles continuously diffuse to the periphery, and under the influence of the movement of the large amount of micro-bubbles, the water with higher lower temperature moves to the surface water, so that the temperature of the surface water is increased, the ice layer near the pile pier and the pier can be melted, and the generation of ice in the water is avoided; the utility model solves the defect that the existing ice melting equipment cannot melt ice in the vicinity of a circular building such as a pile pier, a bridge pier and the like in a targeted manner.

Drawings

Fig. 1 is a schematic view of a microbubble ice melting device near a pile pier or a bridge pier, which is provided by the utility model, installed on the pile pier or the bridge pier;

fig. 2 is a schematic diagram of the overall structure of a microbubble ice melting device near a pier and a pier according to the present utility model;

fig. 3 is a schematic structural diagram of a microbubble assembly of a microbubble ice melting device near a pier or pier according to the present utility model. List of reference numerals:

10. a floatation assembly; 20. a microbubble assembly; 21. micro-gas cells; 22. a microbubble support; 23. a microbubble tube; 24. a connection joint; 30. a connecting piece; 40. pile pier and pier.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the embodiments of the present utility model will be described in further detail with reference to the accompanying drawings.

In the description of the present utility model, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1 to 3, the utility model provides a microbubble deicing device near a pier and a pier, which can solve the defect that existing deicing equipment cannot pertinently defrost the vicinity of a circular building such as the pier and the pier.

The utility model provides a microbubble ice melting device near a pile pier and a pier 40, which comprises a floating assembly 100 and a plurality of microbubble assemblies 20, wherein the floating assembly 10 is connected to the pile pier and the pier 40, and the floating assembly 10 can float near the pile pier and the pier 40; a plurality of microbubble assemblies 20 are connected to the floating assembly 10, and a plurality of microbubble cells 21 are arranged on each microbubble assembly 20.

The height of the microbubble module 20 may be 10cm-20cm, the diameter of the microbubble module 20 may be 30cm-40cm, and the height and the size of the microbubble module 20 may be determined according to practical situations, which is not limited herein.

In this application, the floating assembly 10 can realize the upper and lower floating according to the rising or the decline of the water level near the pier, pier 40, when the water level of pier, pier 40 risees, the floating assembly 10 drives the microbubble assembly 20 to rise, and when the water level of pier, pier 40 descends, the floating assembly 10 drives the microbubble assembly 20 to descend, and the change of the water level near the pier, pier 40 does not influence the melting ice near pier, pier 40.

The microbubble ice melting device near the pile pier and the pier 40 provided by the utility model is connected to the pile pier and the pier 40 through the circular floating assembly 10, and the floating assembly 10 can float near the pile pier and the pier 40; the micro-bubble assemblies 20 are connected to the floating assembly 10, and each micro-bubble assembly 20 is provided with a plurality of micro-bubble holes 21; the floating assembly 10 floats on a water layer near the pile pier and the bridge pier 40, the micro-bubble assembly 20 is positioned in water, air flows out through a plurality of micro-air holes 21, a large number of micro-bubbles are released into the water, the gas content in the water is rapidly and effectively increased, meanwhile, the water is pushed to move, the micro-bubbles have small size and buoyancy, stay in the water for a long time and slowly diffuse upwards, the micro-bubbles continuously diffuse upwards and downwards, and under the influence of the movement of a large number of micro-bubbles, the water with higher lower temperature moves towards the surface water, so that the temperature of the surface water is increased, the ice layer near the pile pier and the bridge pier 40 can be melted, and the generation of ice in the water is avoided; the utility model solves the defect that the existing ice melting equipment cannot melt ice in the vicinity of a circular building such as a pile pier, a bridge pier and the like in a targeted manner.

Referring to fig. 1 to 3, optionally, further comprising: and a plurality of connecting pieces 30, each microbubble module 20 is connected to the floating module 10 through the corresponding connecting piece 30, and the microbubble modules 20 are uniformly arranged near the piers and piers 40.

Wherein, the connecting piece 30 can be the rope, and the quality of rope is light, floats subassembly 10 and floats in the surface of water, and microbubble subassembly 20 is located in the water, and consequently the quality of rope is light can not produce great gravity, has avoided drawing the subassembly 10 of floating into water.

Referring to fig. 1 to 3, alternatively, the floating unit 10 is detachably sleeved on the pier and pier 40, and the plurality of microbubble units 20 are uniformly arranged near the pier and pier 40 with the central axis of the pier and pier 40 as the center of the circle.

Two ropes can be respectively arranged at two ends of the floating assembly 10, the floating assembly 10 is wound on the pile pier and the bridge pier 40, and the two ropes are connected, a preset interval is reserved between the floating assembly 10 and the pile pier and the bridge pier 40, so that when the water level near the pile pier and the bridge pier 40 rises or falls, the floating assembly 10 can float up and down on the pile pier and the bridge pier 40 along with the rise or the fall of the water level; and the micro-bubble assemblies 20 are uniformly arranged near the piers and the piers 40 by taking the central axes of the piers and the piers 40 as circle centers, so that the deicing effect near the piers and the piers 40 is better.

Referring to fig. 3, the microbubble assembly 20 optionally includes a microbubble support 22 and a microbubble tube 23;

the microbubble support 22 is detachably connected with the microbubble tube 23, and a plurality of microbubble holes 21 are formed in the microbubble tube 23.

Wherein, the microbubble support 22 is formed by welding plastic-dipped iron wires, and the microbubble tube 23 is a nano aerator tube. The aperture of the micro-air cells 11 is: phi 0.03 mm-phi 0.06mm; the arrangement density of the micro gas cells 11 is: 700-1200 pieces/meter; the diameter of the microbubbles is: 0.5mm-2mm

Referring to fig. 3, alternatively, the micro air cells 21 are shaped to extend from the middle portion toward both ends, and become gradually larger in size.

Wherein, the shape setting of micro-air bubble 11 can make the formation of bubble more easily, and dwell time is longer in water, and then makes the ice-melt effect near stake pier, pier 40 better.

Optionally, the method further comprises: the fixing piece is detachably connected between the microbubble support piece 22 and the microbubble tube 23, and the microbubble tube 23 is positioned above the microbubble support piece 22.

Wherein, the mounting can be buckle or clamp, and buckle or clamp are convenient in installation or dismantlement process.

Referring to fig. 1 to 3, alternatively, the plurality of microbubble elements 20 are all circular in shape, and the plurality of microbubble elements 20 are combined to form a circular structure.

The microbubble assemblies 20 are combined and surrounded to form a circular structure, and are distributed around the pile pier and the pier 40, so that the ice melting effect near the pile pier and the pier 40 is better.

Alternatively, the number of microbubble modules 20 is 4-8.

The too few microbubble assemblies 20 have no obvious ice melting effect on the vicinity of the piers and piers 40, and the too many microbubble assemblies 20 require more air supply devices, so that the energy consumption is increased.

Optionally, the method further comprises: and the air supply assembly is detachably connected with the micro-bubble assemblies 20 respectively, and is communicated with the interiors of the micro-bubble assemblies 20.

Wherein, the air feed subassembly includes a plurality of gas-supply pipe fittings, air feed pipeline spare and fan, a gas-supply pipe fitting corresponds a microbubble subassembly 20, the one end of gas-supply pipe fitting passes through attach fitting 24 and can dismantle with microbubble subassembly 20 and be connected, and the inside intercommunication of gas-supply pipe fitting and microbubble subassembly 20, the other end of a plurality of gas-supply pipe fittings is connected with the lateral wall of air feed pipeline spare respectively, and the inside intercommunication between air feed pipeline spare all and a plurality of gas-supply pipe fittings, air feed pipeline spare is connected on the fan, in order to make the fan carry the air after the compression to air feed pipeline spare, compressed air gets into in a plurality of gas-supply pipe fittings and the microbubble subassembly 20 again in proper order, finally follow the outflow of gas cell 21.

Further, the three-blade Roots blower is adopted as a compressed air power source by the blower 40, and adopts a three-blade rotor structure, so that the three-blade Roots blower has the advantages of small vibration, low noise, no abrasion of the impeller and the shaft, lasting performance of the three-blade Roots blower, long-term continuous operation, high volume utilization rate, high volumetric efficiency, compact structure and flexible and changeable installation mode.

Optionally, the micro bubble tube 23 is provided with a connection joint 24, and the micro bubble tube 23 is connected with the air supply assembly through the connection joint 24.

Wherein, the connection joint 24 is used for connecting the air supply assembly, provides compressed air for the interior of the micro bubble tube 23, and finally flows out of the micro bubble holes 21.

The working process comprises the following steps: when the microbubble deicing device near the pier and the pier is applied to deicing near the pier and the pier, the floating assembly 10 with the microbubble assembly 20 is sleeved on the pier and the pier 40, the floating assembly 10 floats on a water layer, the microbubble assembly 20 is uniformly arranged in water near the pier and the pier 40, the air supply assembly is started to work, external air is compressed by the air supply assembly and then is input into the microbubble tube 23 and flows out of the microbubble holes 21, a large number of micron-sized microbubbles are released into the water, the gas content in the water is rapidly and effectively increased, the water body is pushed to move at the same time, the microbubbles have small size and small buoyancy, the residence time in the water is long, the upward speed is slow, the microbubbles continuously diffuse to the periphery, and under the influence of the movement of the large number of the microbubbles, the water with higher lower temperature moves to the surface layer water body, so that the temperature of the surface layer water body is increased, and the ice layer near the pier and the pier 40 can be melted.

In summary, the microbubble ice melting device near a pile pier and a pier provided by the utility model is connected to the pile pier and the pier 40 through the circular floating assembly 10, and the floating assembly 10 can float near the pile pier and the pier 40; the micro-bubble assemblies 20 are connected to the floating assembly 10, and each micro-bubble assembly 20 is provided with a plurality of micro-bubble holes 21; the floating assembly 10 floats on a water layer near the pile pier and the bridge pier 40, the micro-bubble assembly 20 is positioned in water, air flows out through a plurality of micro-air holes 21, a large number of micro-bubbles are released into the water, the gas content in the water is rapidly and effectively increased, meanwhile, the water is pushed to move, the micro-bubbles have small size and buoyancy, stay in the water for a long time and slowly diffuse upwards, the micro-bubbles continuously diffuse upwards and downwards, and under the influence of the movement of a large number of micro-bubbles, the water with higher lower temperature moves towards the surface water, so that the temperature of the surface water is increased, the ice layer near the pile pier and the bridge pier 40 can be melted, and the generation of ice in the water is avoided; the utility model solves the defect that the existing ice melting equipment cannot melt ice in the vicinity of a circular building such as a pile pier, a bridge pier and the like in a targeted manner.

It should be noted that not all the steps and modules in the above flowcharts and the system configuration diagrams are necessary, and some steps or modules may be omitted according to actual needs. The execution sequence of the steps is not fixed and can be adjusted as required. The system structure described in the above embodiments may be a physical structure or a logical structure, that is, some modules may be implemented by the same physical entity, or some modules may be implemented by multiple physical entities, or may be implemented jointly by some components in multiple independent devices.

In the above embodiments, the hardware module may be mechanically or electrically implemented. For example, a hardware module may include permanently dedicated circuitry or logic (e.g., a dedicated processor, FPGA, or ASIC) to perform the corresponding operations. The hardware modules may also include programmable logic or circuitry (e.g., a general-purpose processor or other programmable processor) that may be temporarily configured by software to perform the corresponding operations. The particular implementation (mechanical, or dedicated permanent, or temporarily set) may be determined based on cost and time considerations.

While the utility model has been illustrated and described in detail in the drawings and in the preferred embodiments, the utility model is not limited to the disclosed embodiments, and it will be appreciated by those skilled in the art that the code audits of the various embodiments described above may be combined to produce further embodiments of the utility model, which are also within the scope of the utility model.

Claims (7)

1. The microbubble ice melting device near stake mound, pier, its characterized in that includes:

a floating assembly (10), wherein the floating assembly (10) is connected to a pile pier and a pier (40), and the floating assembly (10) can float near the pile pier and the pier (40);

the micro-bubble assembly (20) is connected to the floating assembly (10), and each micro-bubble assembly (20) is provided with a plurality of micro-bubble holes (21);

further comprises: a plurality of connecting pieces (30), wherein each micro-bubble assembly (20) is connected to the floating assembly (10) through the corresponding connecting piece (30), and the micro-bubble assemblies (20) are uniformly arranged near the pier and the pier (40);

the floating assemblies (10) are detachably sleeved on the pile piers and the bridge piers (40), and the micro-bubble assemblies (20) are uniformly arranged near the pile piers and the bridge piers (40) by taking the central axes of the pile piers and the bridge piers (40) as circle centers;

the microbubble assembly (20) comprises a microbubble support (22) and a microbubble tube (23);

the microbubble support piece (22) is detachably connected with the microbubble tube (23), and a plurality of microbubble holes (21) are formed in the microbubble tube (23).

2. The micro-bubble ice-melting device near the pier and pier according to claim 1, wherein the micro-bubble holes (21) extend from the middle to the two ends and become larger gradually.

3. The micro-bubble deicing device near a pier or pier according to claim 1, further comprising: the micro bubble support piece (22) is detachably connected with the micro bubble pipe (23) through the fixing piece, and the micro bubble pipe (23) is located above the micro bubble support piece (22).

4. The microbubble ice melting device near the pier and pier according to claim 1, characterized in that the shape of the microbubble components (20) is circular arc, and the microbubble components (20) are combined and surrounded into a circular structure.

5. The microbubble deicing device near a pier or pier according to claim 4, characterized in that the number of microbubble components (20) is 4-8.

6. The micro-bubble deicing device near a pier or pier according to claim 5, further comprising: the air supply assembly is detachably connected with the microbubble assemblies (20) respectively, and the air supply assembly is communicated with the interiors of the microbubble assemblies (20).

7. The microbubble ice melting device near the pier and pier according to claim 6, characterized in that a connecting joint (24) is arranged on the microbubble tube (23), and the microbubble tube (23) is connected with the air supply assembly through the connecting joint (24).