CN210032756U

CN210032756U - Sub-control station of concrete water cooling system

Info

Publication number: CN210032756U
Application number: CN201920655471.4U
Authority: CN
Inventors: 张磊; 李超毅; 张国新; 李进; 刘毅; 段逆; 梁楠; 唐铭鸿; 陈学永; 程学俊; 王世军; 刘彤; 杨萍; 姚更正; 刘有志; 王振红; 任明; 朱振泱; 辛建达; 周建江
Original assignee: Huaneng Tibet Brahmaputra Hydropower Development Investment Ltd; China Institute of Water Resources and Hydropower Research; Sinohydro Bureau 5 Co Ltd; Huaneng Group Technology Innovation Center Co Ltd; China Gezhouba Group No 6 Engineering Co Ltd
Current assignee: Huaneng Tibet Brahmaputra Hydropower Development Investment Ltd; China Institute of Water Resources and Hydropower Research; Sinohydro Bureau 5 Co Ltd; Huaneng Group Technology Innovation Center Co Ltd; China Gezhouba Group No 6 Engineering Co Ltd
Priority date: 2019-05-08
Filing date: 2019-05-08
Publication date: 2020-02-07
Anticipated expiration: 2029-05-08

Abstract

The utility model belongs to the technical field of the concrete technique and specifically relates to a concrete leads to water cooling system branch accuse station is related to it can lead to damaging the technical problem who breaks down because of factors such as on-the-spot object collision, rainwater to alleviate current bulky concrete intelligence leads to water monitoring facilities to exist. The sub-control station comprises a room body, a water pipeline and a cooling pipeline; the house body is internally provided with an installation space; the water pipeline is arranged in the installation space, and two ends of the water pipeline extend out of the house body and are respectively communicated with the water inlet pipe and the water outlet pipe; one end of the cooling pipeline is communicated with the water pipeline and is positioned in the installation space; the other end of the cooling pipeline extends out of the house body and is used for being communicated with a cooling water pipe pre-buried in concrete. The house body can make its inside device and part avoid causing the trouble because of factors such as on-the-spot object collision, rainwater lead to damaging, and the extension is located the life of its inside device and part, reduces the work load of maintenance, has reduced the installation hidden danger.

Description

Sub-control station of concrete water cooling system

Technical Field

The utility model belongs to the technical field of the concrete technique and specifically relates to a concrete leads to water cooling system branch accuse station is related to.

Background

Since cracks in concrete are mostly generated by temperature stress, in order to prevent the concrete from generating temperature cracks, cooling water pipes are often arranged on the surface of a silo during the concrete pouring, and the temperature rise of the concrete is restrained by passing water through the cooling water pipes, thereby achieving the purpose of reducing the temperature stress of the concrete.

However, as the large-volume concrete construction site in the industries such as water conservancy and hydropower engineering is complex in environment and many in unsafe factors, the intelligent water-passing monitoring equipment for the large-volume concrete on site can be damaged and break down due to factors such as site object collision and rainwater. Meanwhile, when the water-through monitoring equipment is installed, debugged, operated and maintained, the safety of field operation personnel has great hidden danger.

Therefore, the existing intelligent large-volume concrete water-passing monitoring equipment has the technical problem that the equipment can be damaged and break down due to factors such as field object collision and rainwater.

SUMMERY OF THE UTILITY MODEL

The utility model relates to a in view of above-mentioned problem and provide, its aim at provides a concrete leads to water cooling system branch accuse station to it leads to water monitoring facilities to have to lead to damaging the technical problem who breaks down because of factors such as on-the-spot object collision, rainwater to alleviate current bulky concrete intelligence.

For realizing the purpose of the utility model, the following technical proposal is adopted:

a sub-control station of a concrete water cooling system comprises a room body, a water pipeline and a cooling pipeline;

the house body is internally provided with an installation space;

the water pipeline is arranged in the installation space, and two ends of the water pipeline extend out of the room body and are respectively communicated with the water inlet pipe and the water outlet pipe;

one end of the cooling pipeline is communicated with the water pipeline and is positioned in the installation space; and the other end of the cooling pipeline extends out of the room body and is used for being communicated with a cooling water pipe pre-buried in concrete.

Furthermore, the water pipeline comprises a first pipeline, a second pipeline, a third pipeline and a fourth pipeline;

the first pipeline is communicated with the third pipeline; the second pipeline is communicated with the fourth pipeline;

one end of the first pipeline, which is far away from the third pipeline, is communicated with the water inlet pipe;

one end of the second pipeline, which is far away from the fourth pipeline, is communicated with the water drainage pipe;

one end of the third pipeline, which is far away from the first pipeline, and one end of the fourth pipeline, which is far away from the second pipeline, are both closed; the third pipeline is provided with the cooling pipeline communicated with the water inlet end of the cooling water pipe pre-buried in the concrete, and the fourth pipeline is provided with the cooling pipeline communicated with the water outlet end of the cooling water pipe pre-buried in the concrete.

Furthermore, the cooling pipeline is provided with a regulating valve, and the cooling pipeline communicated with the water inlet end of the cooling water pipe pre-embedded in the concrete is also provided with a flow measurement and control device.

Furthermore, the concrete water cooling system sub-control station further comprises a measurement and control box located in the installation space, and the measurement and control box is connected with the flow measurement and control device through a cable.

Furthermore, a bridge is arranged on the side wall of the house body and used for supporting the cables.

Furthermore, a cable hole for avoiding the cable is formed in the bottom wall of the house body, a cover plate is arranged on the cable hole, and the cover plate is pivoted on the bottom wall of the house body and used for covering the cable hole.

Furthermore, a hook is arranged on the side wall of the house body, and the measurement and control box is hung on the hook.

Furthermore, an entrance is arranged on the side wall of the house body, and a door body is arranged at the entrance.

Furthermore, a hanging ring is arranged on the top surface of the house body.

Further, rollers are provided on the bottom surface of the house body.

Technical scheme more than combining, the utility model discloses following beneficial effect has:

the branch control station of the concrete water cooling system comprises a room body, a water pipeline and a cooling pipeline; the house body is internally provided with an installation space; the water pipeline is arranged in the installation space, and two ends of the water pipeline extend out of the house body and are respectively communicated with the water inlet pipe and the water outlet pipe; one end of the cooling pipeline is communicated with the water pipeline and is positioned in the installation space; the other end of the cooling pipeline extends out of the house body and is used for being communicated with a cooling water pipe pre-buried in concrete.

In the branch control station of the concrete water cooling system, the water pipeline and the cooling pipeline are both positioned in the house body, the house body can protect devices and parts positioned in the house body from being collided by other objects on site, and can also shield the devices and the parts positioned in the house body from wind and rain, namely, the house body can prevent the devices and the parts positioned in the house body from being damaged and broken due to the collision of the objects on site, rain and other factors, the service life of the devices and the parts positioned in the house body is prolonged, and the maintenance workload is reduced. Moreover, field operation personnel can enter the house body for maintenance, and hidden mounting hazards are reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of a sub-control station of a concrete water cooling system provided by an embodiment of the present invention;

FIG. 2 is a schematic diagram of the on-site operation of the sub-control station of the concrete water cooling system provided by the embodiment of the present invention;

fig. 3 is a schematic connection diagram of a water pipeline in a branch control station of the concrete water cooling system provided by the embodiment of the present invention.

Icon: 100-house body; 110-a bridge; 120-a cover plate; 130-hook; 140-a door body; 150-a lifting ring; 160-a roller; 170-antenna support post; 180-lighting holes; 190-a support platform; 200-water pipeline; 210-a first conduit; 220-a second conduit; 230-a third conduit; 231-inlet water temperature sensor; 232-water inlet pressure sensor; 240-fourth line; 241-backwater temperature sensor; 242-return water pressure sensor; 250-a reversing member; 260-a fixed support; 300-a cooling circuit; 310-flow measuring and controlling device; 320-a regulating valve; 400-a measurement and control box; 500-a lighting device; 600-a fan; 700-sealing ring.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" 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 is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, 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 meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The following explains an embodiment of the overall structure of the sub-control station of the concrete water cooling system according to the present invention.

In contrast, the embodiment provides a sub-control station of a concrete water cooling system.

Referring to fig. 1-2, the branch control station of the concrete water cooling system includes a room body 100, a water pipeline 200 and a cooling pipeline 300; the house body 100 has an installation space therein; the water pipeline 200 is arranged in the installation space, and both ends of the water pipeline 200 extend out of the room body 100 and are respectively used for being communicated with a water inlet pipe and a water outlet pipe; one end of the cooling pipe 300 is communicated with the water pipe 200 and is positioned in the installation space; the other end of the cooling pipeline 300 extends out of the house body 100 and is used for being communicated with a cooling water pipe pre-buried in concrete.

In the branch control station of the concrete water cooling system, the water pipeline 200 and the cooling pipeline 300 are both located inside the room body 100, the room body 100 can protect the devices and parts located inside the room body from being collided by other objects on site, and can also shield the devices and parts located inside the room body from wind and rain, that is, the room body 100 can prevent the devices and parts located inside the room body from being damaged and broken due to the collision of objects on site, rain and other factors, so that the service life of the devices and parts located inside the room body is prolonged, and the maintenance workload is reduced. Moreover, field operators can enter the house body 100 for maintenance, and hidden installation troubles are reduced.

The house body 100 of the present embodiment is provided in a rectangular parallelepiped structure.

The cooling loop of the sub-control station of the concrete water cooling system is as follows:

referring to fig. 3, the water pipeline 200 includes a first pipeline 210, a second pipeline 220, a third pipeline 230 and a fourth pipeline 240; the first line 210 and the third line 230 are in communication; the second and

fourth conduits

220, 240 are in communication; the end of the first pipe 210 facing away from the third pipe 230 is used for communicating with a water inlet pipe; the end of the second pipe 220 facing away from the fourth pipe 240 is used for communication with a drain; the end of the third pipe 230 facing away from the first pipe 210 and the end of the fourth pipe 240 facing away from the second pipe 220 are both closed; the third pipe 230 is provided with a cooling pipe 300 communicated with a water inlet end of a cooling water pipe pre-buried in concrete, and the fourth pipe 240 is provided with a cooling pipe 300 communicated with a water outlet end of the cooling water pipe pre-buried in concrete.

Wherein, sealing rings 700 are respectively arranged between the first pipeline 210 and the mounting hole of the house body 100 and between the second pipeline 220 and the mounting hole of the house body 100, and the sealing rings 700 can prevent rainwater from entering the inside of the house body 100. The first pipe 210 and the second pipe 220 are sleeved with a fixing support 260, and the fixing support 260 is installed on the bottom surface of the house body 100 for supporting the first pipe 210. The fixing supporter 260 may be configured as a clip or a bracket.

The third pipe 230 is sleeved with the fixing support 260 on the third pipe 230. The third pipeline 230 is further provided with a water inlet temperature sensor 231 and a water inlet pressure sensor 232, which are respectively used for measuring the temperature and the pressure of the cooling water entering the cooling water pipe pre-embedded in the concrete.

The fourth pipe 240 is sleeved with the fixing support 260 on the fourth pipe 240. A return water temperature sensor 241 and a return water pressure sensor 242 are further disposed on the fourth pipeline 240 of the fourth pipeline 240, and are respectively used for measuring the temperature and the pressure of the cooling water discharged through the cooling water pipes pre-buried in the concrete.

The first pipeline 210 and the third pipeline 230, and the second pipeline 220 and the fourth pipeline 240 are communicated through the reversing piece 250. The direction-changing member 250 is provided as a direction-changing valve, the direction-changing member 250 is configured to make the first pipeline 210 communicate with the third pipeline 230 and the third pipeline 230 of the first pipeline 210, the second pipeline 220 communicates with the fourth pipeline 240 and the fourth pipeline 240, the cooling water of the first pipeline 210 can only flow to the third pipeline 230 of the third pipeline 230, and the water of the fourth pipeline 240 can only flow to the second pipeline 220 of the second pipeline 220 to complete the water circulation.

The cooling pipeline 300 is provided with an adjusting valve 320, the adjusting valve 320 is used for controlling the flow of the cooling pipeline 300, a worker can manually control the adjusting valve 320, and the adjusting valve 320 can be set as a manual ball valve. The cooling pipeline 300 communicated with the water inlet end of the cooling water pipe pre-buried in the concrete is also provided with a flow measurement and control device 310, and the flow measurement and control device 310 is used for monitoring the flow of the cooling pipeline 300 communicated with the water inlet end of the cooling water pipe pre-buried in the concrete. The flow measurement and control device 310 may be configured as a sensor. The bottom of the flow measurement and control device 310 is provided with a supporting platform 190, and the supporting platform 190 is installed on the bottom surface of the room body 100 and used for supporting the flow measurement and control device 310.

Cooling circuit 300 includes multiple sections: one end of the first straight pipeline is communicated with the third pipeline 230 or the fourth pipeline 240 of the third pipeline 230 or the fourth pipeline 240, and the other end of the first straight pipeline is communicated with the regulating valve 320; one end of the second section of straight pipeline is communicated with one end of the regulating valve 320, which is far away from the first section of straight pipeline, and the other end of the second section of straight pipeline is communicated with the elbow connector; one end of the third section of straight pipeline is communicated with one end of the elbow joint, which is far away from the second section of straight pipeline, and the other end of the third section of straight pipeline is communicated with a cooling water pipe pre-buried in the concrete. In addition, the cooling pipeline 300 communicated with the third pipeline 230 of the third pipeline 230 further includes a movable joint and a fourth straight pipeline, two ends of the flow measurement control device 310 are respectively communicated with one end of the third straight pipeline, which is deviated from the bent joint, and the fourth straight pipeline through the movable joint, and one end of the fourth straight pipeline, which is deviated from the movable joint, is communicated with the cooling water pipe pre-embedded in the concrete. In addition, the number of the cooling pipelines 300 communicating with the third pipeline 230, the third pipeline 230 and the fourth pipeline 240 may be plural, and three cooling pipelines are provided in the present embodiment.

In addition, the branch control station of the concrete water cooling system further comprises a measurement and control box 400 located in the installation space, and the measurement and control box 400 is connected with the flow measurement and control device 310 through a cable. The inlet water temperature sensor 231, the inlet water pressure sensor 232, the return water temperature sensor 241 and the return water pressure sensor 242 are all connected with the measurement and control box 400 through cables.

To facilitate the management and storage of cables, a bridge 110 is provided on the side wall of the house body 100, the bridge 110 supporting the cables. Meanwhile, the bridge frame 110 is arranged on the side wall of the house body 100, so that the cable is isolated from the bottom surface of the house body 100, the cable is prevented from being protected, the cable is prevented from being treaded by workers and abraded, and the situation that the detection and maintenance of the workers are influenced due to disorder of the cable can be further prevented. The bridge 110 may be configured as a support plate mounted on the side wall of the house body 100, and a baffle is disposed on a side of the support plate facing away from the side wall of the house body 100.

In addition, the cable of the temperature sensor of the cooling water pipe pre-buried in the concrete needs to enter the inside of the room body 100 to be connected with the measurement and control box 400, and therefore, a cable hole for avoiding the cable is formed in the bottom wall of the room body 100. In order to prevent rainwater and other impurities from entering the inside of the house body 100 through the cable hole, a cover plate 120 is provided on the cable hole, and the cover plate 120 is pivoted on the bottom wall of the house body 100 to cover the cable hole.

In order to save the space inside the room body 100 and improve the space utilization rate, the hook 130 is provided on the sidewall of the room body 100, and the measurement and control box 400 is hung on the hook 130. Each of the measurement and control boxes 400 is supported by two hooks 130. The hook 130 can be glued to the sidewall of the house 100 or can be fastened to the sidewall of the house 100. A signal line avoiding hole is further formed in the top surface of the house body 100, and the signal line of the measurement and control box 400 extends out of the house body 100 through the signal line avoiding hole. An antenna support column 170 is further provided on the top surface of the house body 100, and a wire number is mounted on the antenna support column 170.

In addition, in order to facilitate the entrance and exit of the worker into and out of the house body 100, an entrance is opened on a side wall of the house body 100, and a door body 140 is installed at the entrance. One side of the door 140 is pivotally connected to a sidewall of the doorway. A handle is further disposed on the door body 140 to facilitate the opening or closing of the door body 140 by a worker.

In addition, a hanging ring 150 is provided on the top surface of the house body 100 so as to lift the house body 100 to move the house body 100. The hoist ring 150 is configured to be hoisted to a gantry or the like. In this embodiment, the hanging rings 150 are disposed at four corners of the house 100. But is not limited thereto, at least one hanging ring 150 may be provided at the center of the top surface of the house body 100.

In order to adjust the position of the house body 100, rollers 160 are disposed on the bottom surface of the house body 100, the rollers 160 are disposed at four corners of the house body 100, and the rollers 160 are universal wheels with brakes. The worker may push the house body 100 to move to avoid other devices.

The side surface of the house body 100 is further provided with a lighting hole 180, and the lighting hole 180 can be a rectangular hole.

The lighting device 500 is arranged on the top wall of the house body 100, the lighting device 500 can be set as an electric lamp, and the lighting device 500 can provide light for workers to conveniently overhaul.

The side wall of the house body 100 is further provided with a fan 600, the inside of the house body 100 is further provided with a power socket and a stabilized voltage power supply, the lighting device 500 and the fan 600 are respectively connected with different power sockets through cables, and the power sockets are electrically connected with the stabilized voltage power supply.

A lightning protection device is also arranged outside the house body 100, and the lightning protection device can be a lightning rod.

The body 100 is also coated with a fire retardant coating.

In summary, the sub-control station of the concrete water cooling system provided by the embodiment has the following advantages:

(1) the water pipeline 200 and the cooling pipeline 300 are both located inside the room body 100, the room body 100 can protect the devices and parts located inside the room body from being collided by other objects on site, and can also shield the devices and parts located inside the room body from wind and rain, namely, the room body 100 can prevent the devices and parts located inside the room body from being damaged and broken due to the collision of objects on site, rain and other factors, so that the service life of the devices and parts located inside the room body is prolonged, and the maintenance workload is reduced. Moreover, field operators can enter the house body 100 for maintenance, and hidden installation troubles are reduced.

(2) The size of the house body 100, the number of the internal water pipeline 200, the monitoring equipment and other accessories can be flexibly configured according to the actual situation of the site, so as to meet the water monitoring range of different areas of the site.

(3) The accessories such as the water pipeline 200, the monitoring equipment and the like are intensively arranged inside the house body 100, so that the on-site water cooling system can be conveniently managed, and the requirements of on-site civilized construction and environmental protection are met.

(4) The bottom of the house body 100 is provided with the roller 160, the top of the house body is provided with the hanging ring 150, the concrete water cooling system sub-control station can be integrally transported to another position conveniently on site to carry out water supply measurement and control operation, and no extra water monitoring equipment and installation operation of accessories such as related pipelines and pipe fittings are needed, so that the construction difficulty is greatly reduced, and the working efficiency is improved.

(5) The lightning protection device has the advantages of simple structure, convenience in manufacturing, low cost, strong practicability and lightning protection function, and can work under severe weather conditions.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims

1. A sub-control station of a concrete water cooling system is characterized by comprising a room body, a water pipeline and a cooling pipeline;

the house body is internally provided with an installation space;

2. The concrete water cooling system substation of claim 1, wherein the water pipeline comprises a first pipeline, a second pipeline, a third pipeline and a fourth pipeline;

3. The sub-control station of the concrete water cooling system according to claim 1, wherein the cooling pipeline is provided with an adjusting valve, and the cooling pipeline communicated with the water inlet end of the cooling water pipe pre-embedded in the concrete is further provided with a flow measurement and control device.

4. The sub-control station of the concrete water-cooling system according to claim 3, further comprising a measurement and control box located in the installation space, wherein the measurement and control box is connected with the flow measurement and control device through a cable.

5. The concrete water cooling system substation of claim 4, wherein a bridge is arranged on a side wall of the house body, and the bridge is used for supporting the cable.

6. The branch control station of a concrete water-through cooling system as claimed in claim 5, wherein a cable hole for avoiding the cable is opened on the bottom wall of the house body, a cover plate is provided on the cable hole, and the cover plate is pivoted on the bottom wall of the house body and used for covering the cable hole.

7. The branch control station of the concrete water cooling system according to claim 4, wherein a hook is arranged on a side wall of the house body, and the measurement and control box is hung on the hook.

8. The branch control station of the concrete water cooling system according to claim 1, wherein an entrance is formed in a side wall of the house body, and a door body is installed at the entrance.

9. The branch control station of the concrete water cooling system according to claim 1, wherein a hanging ring is arranged on the top surface of the house body.

10. The sub-control station of the concrete water cooling system according to claim 1, wherein rollers are provided on the bottom surface of the house body.