CN217923581U - Cooling system for large-volume bearing platform concrete curing - Google Patents

Abstract

The utility model relates to a cooling system for bulky cushion cap concrete maintenance relates to bulky cushion cap cooling's technical field, including condenser tube, condenser tube dispels the heat to cushion cap inside through water supply mechanism, and water supply mechanism includes water storage box, suction pump and circulation subassembly, and the circulation subassembly includes circulating pipe and circulating pump. The suction pump starts to make the cooling water get into and cool down to cushion cap inside in the condenser tube, the cooling water behind the condenser tube collects circulating pipe in, the circulating pump starts, the water storage box is got back to the cooling water under the suction effect of circulating pump, with this cyclic utilization who realizes the cooling water, thereby the probability of direct emission after having reduced the cooling water use, the waste of water resource among the bulky cushion cap concrete curing process has been reduced, cool down the cooling water through cooling mechanism simultaneously, the cooling effect of cooling water circulation use among the bulky cushion cap concrete curing process has been improved.

Description

Cooling system for large-volume bearing platform concrete curing

Technical Field

The application relates to the technical field of cooling of large-volume bearing platforms, in particular to a cooling system for concrete curing of large-volume bearing platforms.

Background

The bearing platform is a reinforced concrete platform which is arranged at the top of a pile foundation and is used for connecting the tops of all piles for bearing and distributing loads transmitted by a pier body, and the bearing platform is a connection part between a pile and a column or a pier, for example, a connection part between a pier and the pile in bridge engineering is the bearing platform; the large-volume concrete refers to large-volume concrete with the minimum geometric dimension of a concrete structure object not less than 1m, so that bearing platforms with the geometric dimension of more than 1m are large-volume bearing platforms; the concrete cross-sectional dimension of bulky cushion cap is great, and in the work progress, the hydration reaction of cement can produce a large amount of heat of hydration, and concrete itself is not heat-conducting, and consequently the inside heat of concrete is difficult for giving off, but the concrete surface heat dissipation is very fast, so cushion cap inside and outside difference in temperature is great, and inside and outside difference in temperature great can make the concrete produce the crack to influence the safety and subsequent normal use of cushion cap structure.

In the current work progress, through pre-buried condenser tube in the cushion cap, it reduces the inside temperature of concrete to last to lead to water, rivers in the condenser tube directly discharge after the cushion cap is inside, with this dispel the heat to cushion cap inside, thereby carry out the maintenance to cushion cap concrete, make the concrete reduce the probability of fracture at the in-process of sclerosis and gaining in strength, but the concrete use amount of bulky cushion cap is great, consequently, need a large amount of cooling water to cool down to cushion cap inside, cooling rivers directly discharge and can cause a large amount of water waste after the cushion cap is inside.

SUMMERY OF THE UTILITY MODEL

In order to reduce the waste of water resource in the large-volume cushion cap concrete curing process, the application provides a cooling system for large-volume cushion cap concrete curing.

The application provides a cooling system for maintenance of bulky cushion cap concrete adopts following technical scheme:

the utility model provides a cooling system for maintenance of bulky cushion cap concrete, is including being used for carrying out radiating condenser tube to cushion cap inside, condenser tube dispels the heat to cushion cap inside through water supply mechanism, water supply mechanism includes:

the water storage tank is arranged on the ground and used for storing cooling water;

the water suction pump is arranged on the water storage tank, is connected with the cooling water pipe and is used for sucking water in the water storage tank into the cooling water pipe;

and the circulating assembly is arranged on the water storage tank, is connected with the cooling water pipe and enables cooling water to flow back into the water storage tank.

Through adopting above-mentioned technical scheme, the suction pump starts to aspirate the cooling water in the water storage box, and the cooling water dispels the heat to the cushion cap inside in getting into condenser tube from the water storage box under the suction effect of suction pump, and the water behind the cooling water cooling pipe is got back to in the water storage box under the effect of circulation subassembly to this carries out cyclic utilization to the cooling water, thereby has reduced the probability that the cooling water directly discharged after using, has consequently reduced the waste of bulky cushion cap concrete curing in-process water resource.

Optionally, the circulation component includes:

the circulating water pipe is arranged on the cooling water pipe;

and the circulating pump is arranged on the water storage tank and is connected with the circulating water pipe and used for pumping the cooling water into the water storage tank.

Through adopting above-mentioned technical scheme, during the cooling water in the cooling tube got into circulating pipe after cooling down to the cushion cap, the circulating pump starts to aspirate the water in the circulating pipe for in the cooling water flows through circulating pipe and gets back to the cistern, carry out cyclic utilization to this cooling water, thereby reduced the waste of bulky cushion cap concrete curing in-process water resource.

Optionally, be provided with the cooling mechanism that is used for cooling to the cooling water on the water storage box, cooling mechanism includes:

the cooling tank is arranged on the water storage tank, and the circulating pump is arranged on the cooling tank;

the cooling frame, the cooling frame sets up on the cooler bin, place the ice bag that is used for cooling down to the cooling water in the cooling frame, a plurality of limbers have been seted up on the cooling frame.

Through adopting above-mentioned technical scheme, in the cooling water got into the cooler bin behind the circulating pipe, cool down to the cooling water through the ice bag, the cooling water after the cooling passes through in the limbers gets into the cistern to this cools down the cooling water after being heated in cushion cap inside, thereby the temperature that reduces the cooling water in the cistern risees the probability that produces adverse effect to cushion cap inside cooling effect gradually, consequently, improved the cooling water circulation and used the cooling effect to the bulky cushion cap concrete curing in-process.

Optionally, the cooling frame is slidably disposed on the cooling box, and a positioning assembly for positioning the cooling frame is disposed on the cooling box.

Through adopting above-mentioned technical scheme, open locating component, then can take out the cooling frame and change the ice bag to improved the effect to the cooling water cooling of circulation, the ice bag after the use freezes again can used repeatedly, thereby practiced thrift the cost, changes the completion back, fixes a position the cooling frame through locating component, with this dismantlement and the installation that realizes the cooling frame, thereby has improved the convenience that the cooling frame was dismantled and was installed.

Optionally, the positioning assembly includes:

the clamping block is arranged on the cooling frame and is clamped on the cooling box;

the locating plate, the locating plate setting is on the cooling frame and supports and press on the cooler bin, be provided with the handle of the pulling of being convenient for on the locating plate.

Through adopting above-mentioned technical scheme, the pulling handle makes the locating plate break away from the cooler bin, and the joint piece breaks away from the cooler bin simultaneously, then can take off the cooling frame and change the ice bag, and the back that finishes is changed, promotes the handle and makes joint piece joint install on the cooler bin, and the locating plate supports to press simultaneously and fixes a position the cooling frame on the cooler bin to this dismantlement and the installation location that realizes the cooling frame, thereby has improved the convenience that the cooling frame was dismantled and was installed the location.

Optionally, a sealing ring convenient for sealing is arranged on the positioning plate.

Through adopting above-mentioned technical scheme, the sealing washer seals locating plate and cooler bin contact department to reduce the probability that cooling water spills over from locating plate and cooler bin contact department, thereby improved the leakproofness of cooler bin, with this waste that has reduced the water resource.

Optionally, a guide plate for guiding water flow is arranged on the cooling box, a plurality of guide holes with a diameter smaller than that of the water through holes are formed in the guide plate, and the guide holes enable water flow to uniformly pass through the guide plate and then enter the cooling frame.

Through adopting above-mentioned technical scheme, the cooling water collects on the deflector after getting into the cooler bin, the cooling water passes through and gets into the cooling frame behind the guiding hole, the aperture of guiding hole is less, thereby the velocity of flow of cooling water reduces, consequently, the cooling water can overflow whole deflector and flow to the cooling frame through a plurality of guiding holes uniformly, thereby make cooling water can be even cool down through the ice bag, with this reduce the probability that the cooling water only cooled down through the fixed position on the cooling frame, consequently, the effect of cooling water has been improved.

Optionally, a temperature sensor for displaying temperature is arranged on the circulating water pipe.

Through adopting above-mentioned technical scheme, temperature sensor detects circulating pipe's temperature to this obtains the inside temperature of cushion cap, thereby according to the inside temperature regulation ice bag's of cushion cap quantity, makes the inside temperature of cushion cap satisfy the condition of cushion cap concrete maintenance, has consequently improved the convenience to bulky cushion cap concrete maintenance process monitoring.

In summary, the present application includes at least one of the following beneficial technical effects:

the suction pump starts to make the cooling water get into in the condenser tube to cool down to the cushion cap inside, the cooling water behind the condenser tube collects in circulating pipe, the circulating pump starts to suction the cooling water in the circulating pipe, the cooling water gets into in the cooler bin under the suction effect of circulating pump, go into in the cistern through the ice bag in the cooling frame after cooling down, with this cyclic utilization that realizes the cooling water, thereby the probability of direct emission after the cooling water uses has been reduced, the waste of water resource in the bulky cushion cap concrete curing process has been reduced, simultaneously through cooling down to the cooling water, the cooling effect of cooling water cyclic utilization in the bulky cushion cap concrete curing process has been improved.

Drawings

FIG. 1 is a schematic overall structure of the present application;

FIG. 2 is a schematic view of the structure of the cooling water pipe in the present application;

fig. 3 is a schematic structural diagram of the temperature reducing mechanism in the present application, in which a cooling tank is sectioned.

Reference numerals: 1. a bearing platform; 11. a cooling water pipe; 111. a water inlet end; 112. a water outlet end; 12. a connecting pipe; 121. a water delivery part; 122. a connecting portion; 13. a water outlet pipe; 131. a communicating portion; 132. a water outlet part; 2. a water supply mechanism; 21. a water storage tank; 211. a water injection pipe; 22. a water pump; 23. a circulation component; 231. a circulating water pipe; 232. a circulation pump; 233. a temperature sensor; 3. a cooling mechanism; 31. a cooling tank; 311. a sliding hole; 312. a clamping groove; 32. a cooling frame; 321. a water through hole; 4. a positioning assembly; 41. a clamping block; 42. positioning a plate; 421. a handle; 422. a seal ring; 5. a guide plate; 51. and (4) a guide hole.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The model number of the temperature sensor 233 in the embodiment of the present application is SSM-T20.

The embodiment of the application discloses a cooling system for large-volume cushion cap concrete curing.

Referring to fig. 1 and 2, a cooling system for mass bearing platform concrete curing comprises a cooling water pipe 11 for dissipating heat inside a bearing platform 1, wherein the cooling water pipe 11 dissipates heat inside the bearing platform 1 through a water supply mechanism 2.

Referring to fig. 1 and 2, the cooling water pipes 11 are provided with a plurality of groups, the plurality of groups of cooling water pipes 11 are fixedly installed inside the bearing platform 1 at intervals from top to bottom, each group of cooling water pipes 11 is composed of a plurality of cooling water pipes 11 in a horizontal state, each group of cooling water pipes 11 only has one water inlet end 111 and one water outlet end 112, the water inlet ends 111 of the plurality of groups of cooling water pipes 11 are connected together through the connecting pipe 12, and the water outlet ends 112 of the plurality of groups of cooling water pipes 11 are connected together through the water outlet pipe 13.

Referring to fig. 2, the connecting pipe 12 includes a water delivery part 121 and two connecting parts 122 integrally arranged together, the two connecting parts 122 are located at one end of the water delivery part 121 close to the cooling water pipes 11, and the two connecting parts 122 are respectively connected with the water inlet ends 111 of the two groups of cooling water pipes 11; the water outlet pipe 13 includes a communication portion 131 and two water outlet portions 132 integrally disposed together, the two water outlet portions 132 are respectively connected to the water outlet ends 112 of the two sets of cooling water pipes 11, and the communication portion 131 is located at one end of each of the two water outlet portions 132 away from the cooling water pipes 11.

Referring to fig. 1 and 2, the water supply mechanism 2 includes a water storage tank 21, a suction pump 22 and a circulation assembly 23, the water storage tank 21 is fixedly installed on the ground, a water injection pipe 211 for injecting cooling water is fixedly installed on the upper surface of the water storage tank 21, and the water storage tank 21 is used for storing cooling water; the water suction pump 22 is fixedly arranged on the outer side wall of the water storage tank 21 close to the bearing platform 1, the water suction pump 22 is communicated with the inside of the water storage tank 21, and the water suction pump 22 is connected with the water delivery part 121 and is used for sucking cooling water in the water storage tank 21 into the cooling water pipe 11; the suction pump 22 is activated to pump the cooling water into the cooling water pipe 11 to cool the inside of the platform 1, and the cooling water passes through the cooling water pipe 11 and is collected in the communication portion 131.

Referring to fig. 1 and 2, the circulation unit 23 is disposed on the water storage tank 21 and connected to the cooling water pipe 11, the circulation unit 23 includes a circulation water pipe 231 and a circulation pump 232, one end of the circulation water pipe 231 is connected to the communicating part 131, a temperature sensor 233 for displaying temperature is fixedly mounted on one end of the circulation water pipe 231 connected to the communicating part 131, and the temperature of the cooling water is detected by the temperature sensor 233 to obtain the temperature inside the platform 1; the circulation pump 232 is fixedly installed on the water storage tank 21, the circulation pump 232 is connected to one end of the circulation pipe 231 away from the communication portion 131, and the circulation pump 232 is used for sucking the cooling water into the water storage tank 21.

Referring to fig. 1 and 3, a cooling mechanism 3 for cooling water is arranged on the water storage tank 21, the cooling mechanism 3 includes a cooling tank 31 and a cooling frame 32, the cooling tank 31 is fixedly mounted on the upper surface of the water storage tank 21 and is communicated with the inside of the water storage tank 21, and a circulating pump 232 is fixedly mounted on the upper surface of the cooling tank 31 and is communicated with the inside of the cooling tank 31; the circulation pump 232 is activated, and the cooling water flows from the communication portion 131 through the circulation pipe 231 by the circulation pump 232 and enters the cooling tank 31.

Referring to fig. 1 and 3, a horizontal sliding hole 311 is formed in the outer side wall of the cooling tank 31, the cooling frame 32 is slidably mounted on the sliding hole 311, a plurality of ice bags for cooling water are placed on the cooling frame 32, a plurality of water through holes 321 for passing cooling water are formed in the cooling frame 32, and the cooling water enters the water storage tank 21 through the water through holes 321 after being cooled by the ice bags; the cooling box 31 is provided with a positioning unit 4 for positioning the cooling frame 32.

Referring to fig. 1 and 3, the positioning assembly 4 includes a clamping block 41 and a positioning plate 42, the clamping block 41 is fixedly mounted on the outer side wall of the cooling frame 32, a clamping groove 312 is formed on the inner side wall of the cooling box 31, and the clamping block 41 is clamped and mounted on the clamping groove 312; locating plate 42 fixed mounting is on the lateral wall that cooling frame 32 deviates from joint piece 41, and locating plate 42 supports and presses on the cooling tank 31 lateral wall, and fixed mounting has the handle 421 of the pulling of being convenient for on the locating plate 42 lateral wall, and fixed mounting has the sealing washer 422 of being convenient for to seal on the locating plate 42 deviates from the inside wall of handle 421, and sealing washer 422 is used for blockking that the cooling water spills over.

Referring to fig. 1 and 3, the handle 421 is pulled to separate the positioning plate 42 from the cooling box 31, and the clamping block 41 is separated from the clamping groove 312, so that the cooling frame 32 can be taken down to replace the ice bag, thereby improving the effect of cooling the circulating cooling water, and the used ice bag can be reused after being frozen again, thereby saving the cost; after the change finishes, promote handle 421 and make the joint of joint piece 41 joint install on joint groove 312, locating plate 42 supports simultaneously and presses on cooling box 31 to this fixes a position cooling frame 32, thereby has improved the convenience of cooling frame 32 dismantlement and installation location.

Referring to fig. 3, a guide plate 5 for guiding water flow is fixedly mounted on the inner side wall of the cooling box 31, the guide plate 5 is in a horizontal state and is located above the cooling frame 32, a plurality of guide holes 51 with apertures smaller than the water through holes 321 are formed in the guide plate 5, cooling water enters the cooling box 31 and then enters the cooling frame 32 through the guide holes 51, the apertures of the guide holes 51 are small, so that the flow rate of the cooling water is reduced, therefore, the cooling water can overflow the whole guide plate 5, then the cooling water uniformly flows to the cooling frame 32 through the guide holes 51, so that the cooling water can be uniformly cooled through an ice bag, the probability that the cooling water is cooled only through a fixed position on the cooling frame 32 is reduced, and therefore, the cooling effect of the cooling water is improved.

The working principle of the embodiment of the application is as follows:

the water pump 22 is started to enable cooling water to enter the cooling water pipe 11, the cooling water is collected into the circulating water pipe 231 after cooling the interior of the bearing platform 1, the circulating pump 232 is started to suck the cooling water, the cooling water enters the cooling tank 31 through the circulating water pipe 231, the cooling water is collected on the guide plate 5 and uniformly flows into the cooling frame 32 through the guide holes 51, the ice bags in the cooling frame 32 cool the cooling water, and the cooled cooling water flows into the water storage tank 21 through the water through holes 321, so that recycling of the cooling water is achieved, the probability of direct discharge of the cooling water after use is reduced, waste of water resources in the large-volume bearing platform concrete curing process is reduced, and meanwhile, the cooling effect of the cooling water in the large-volume bearing platform concrete curing process due to recycling of the cooling water is improved.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a cooling system for maintenance of bulky cushion cap concrete, is including being used for carrying out radiating condenser tube (11) to cushion cap (1) inside, its characterized in that: condenser tube (11) are through supplying water mechanism (2) to the inside heat dissipation that carries out of cushion cap (1), water supply mechanism (2) include:

the water storage tank (21) is arranged on the ground and used for storing cooling water;

the water suction pump (22) is arranged on the water storage tank (21) and connected with the cooling water pipe (11) and is used for sucking water in the water storage tank (21) into the cooling water pipe (11);

and the circulating assembly (23) is arranged on the water storage tank (21), is connected with the cooling water pipe (11) and enables cooling water to flow back into the water storage tank (21).

2. The cooling system for large-volume bearing platform concrete curing of claim 1, wherein: the circulation assembly (23) comprises:

a circulating water pipe (231), wherein the circulating water pipe (231) is arranged on the cooling water pipe (11);

a circulation pump (232), the circulation pump (232) being disposed on the water storage tank (21) and connected with the circulation water pipe (231) and serving to pump the cooling water into the water storage tank (21).

3. The cooling system for large-volume cap concrete curing of claim 2, wherein: be provided with on water storage box (21) and be used for carrying out cooling mechanism (3) that cool down to the cooling water, cooling mechanism (3) include:

a cooling tank (31), wherein the cooling tank (31) is arranged on the water storage tank (21), and the circulating pump (232) is arranged on the cooling tank (31);

the cooling frame (32), cooling frame (32) set up on cooling tank (31), place the ice bag that is used for cooling down to the cooling water in cooling frame (32), a plurality of limbers (321) have been seted up on cooling frame (32).

4. The cooling system for large-volume concrete maintenance of a bearing platform according to claim 3, wherein: the cooling frame (32) is arranged on the cooling box (31) in a sliding mode, and a positioning assembly (4) used for positioning the cooling frame (32) is arranged on the cooling box (31).

5. The cooling system for large-volume concrete cap curing according to claim 4, wherein: the positioning assembly (4) comprises:

the clamping block (41) is arranged on the cooling frame (32) and clamped on the cooling box (31);

locating plate (42), locating plate (42) set up on cooling frame (32) and support and press on cooler bin (31), be provided with handle (421) of being convenient for the pulling on locating plate (42).

6. The cooling system for large-volume concrete maintenance of a bearing platform according to claim 5, wherein: and a sealing ring (422) convenient to seal is arranged on the positioning plate (42).

7. The cooling system for large-volume concrete maintenance of a bearing platform according to claim 3, wherein: the cooling box (31) is provided with a guide plate (5) used for guiding water flow, a plurality of guide holes (51) with the hole diameter smaller than the water through holes (321) are formed in the guide plate (5), and the guide holes (51) enable the water flow to uniformly pass through the guide plate (5) and then enter the cooling frame (32).

8. The cooling system for large-volume concrete cap curing of claim 2, wherein: and a temperature sensor (233) for displaying temperature is arranged on the circulating water pipe (231).

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