Rescue station heat dissipation management system
By combining temperature controllers and water pumps with heat dissipation pipes, water curtain mechanisms, and cooling devices, the problem of high temperature at the top of the container station was solved, achieving a low-cost and low-energy cooling effect inside the station.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HANGZHOU RONGCHENG ROAD ENGINEERING CO LTD
- Filing Date
- 2025-08-01
- Publication Date
- 2026-06-09
AI Technical Summary
The container station's iron material causes the container surface temperature to become too high when exposed to direct sunlight in summer. The existing air conditioning is not effective in cooling the interior, resulting in excessively high temperatures inside the station.
A temperature controller is used to detect the top temperature and control the water pump. The temperature at the top of the station is reduced through heat dissipation pipes and water curtain mechanism. Fans are used to accelerate the cooling and circulation of water. Cooling columns and sponges are used to increase the air contact area for heat dissipation.
It effectively reduces the temperature inside the rest stop, achieving a low-cost and low-energy heat dissipation effect. The temperature inside the rest stop is reduced through the circulation cooling of the water curtain mechanism and cooling device.
Smart Images

Figure CN224340259U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of rescue station technology, and in particular to a heat dissipation management system for rescue stations. Background Technology
[0002] Container stations are typically used as temporary facilities to provide aid, shelter, medical care, and other basic living necessities to people in need. They are convenient, quick, and inexpensive to set up, and are often placed along roadsides as rescue stations. However, the containers themselves are primarily made of iron, and in summer, the direct sunlight can cause the surface temperature of the containers to reach over 70 degrees Celsius. Although rescue stations are equipped with air conditioning for indoor cooling, the cooling effect is not significant, resulting in excessively high temperatures inside the stations. Summary of the Invention
[0003] To solve the above-mentioned technical problems, this utility model provides a heat dissipation management system for rescue stations, which can reduce the temperature at the top of the rescue station, thereby reducing the temperature inside the rescue station.
[0004] To solve the above problems, the present invention adopts the following technical solution:
[0005] This utility model discloses a heat dissipation management system for a rescue station, comprising a temperature controller, a water curtain mechanism, a water tank, heat dissipation pipes, and a water pump. The heat dissipation pipes include multiple heat exchange pipes evenly laid on the top of the rescue station and connected end to end. The inlet end of the heat dissipation pipes is connected to the outlet end of the water tank via the water pump. The water curtain mechanism includes a fan, a water distribution trough, a water curtain, and a water collection trough. The outlet end of the heat dissipation pipes is connected to the inlet end of the water distribution trough, the inlet end of the water curtain is connected to the outlet end of the water distribution trough, the outlet end of the water curtain is connected to the inlet end of the water collection trough, and the outlet end of the water collection trough is connected to the inlet end of the water tank. The fan is used to blow air onto the water curtain. The temperature controller is electrically connected to the water pump and is used to detect the temperature at the top of the rescue station and control the operation of the water pump according to the temperature.
[0006] In this solution, the temperature controller activates the water pump after detecting that the temperature at the top of the rescue station has reached a preset value. The water pump draws water from the tank into the cooling pipes, which absorb the heat from the top of the rescue station, causing the temperature to drop. The water then flows into the distribution trough and then into the collection trough via the water curtain. Simultaneously, a fan blows air onto the water curtain to cool the water. The cooled water then flows back into the tank through the collection trough, completing the cycle. This solution is low in cost and energy consumption.
[0007] Preferably, the water curtain includes multiple cooling columns arranged side by side, the cooling columns are vertically arranged and their bottom ends are fixedly connected to the water collection tank, the water distribution tank is located above the cooling columns, the water distribution tank is provided with water flow holes corresponding to the positions of the cooling columns, and the air outlet of the fan is directly facing all the cooling columns.
[0008] Preferably, the outer surface of the cooling column has uneven protrusions evenly distributed.
[0009] Preferably, the outer surface of the cooling column is covered with a cooling sponge.
[0010] After absorbing heat, the water flows through the cooling column into the cooling sponge, increasing the contact area with the air and accelerating the cooling of the water.
[0011] The present invention provides a rescue station, comprising a station housing and the aforementioned rescue station heat dissipation management system. The station housing is made of a shipping container, and the heat dissipation pipes are located on the top of the station housing.
[0012] The beneficial effects of this utility model are: the water curtain mechanism can cool the water after it has absorbed heat; the temperature controller can control the water pump to work according to the temperature, so that the heat dissipation pipe can cool the rescue station; the water after absorbing heat flows into the cooling sponge through the cooling column, increasing the contact area with the air and accelerating the cooling of the water. Attached Figure Description
[0013] Figure 1 This is an overhead view of the cooling management system at the rescue station;
[0014] Figure 2 This is a schematic diagram of the water curtain structure;
[0015] Figure 3 This is a cross-sectional view of the cooling column;
[0016] Figure 4 This is a top view of the station box.
[0017] In the diagram: 1. Water curtain mechanism, 11. Fan, 12. Water distribution trough, 121. Water outlet, 13. Water collection trough, 14. Cooling column, 141. Protrusion, 15. Cooling sponge, 2. Water tank, 3. Water pump, 4. Station box, 5. Heat exchange pipe, 6. Temperature controller. Detailed Implementation
[0018] The technical solution of this utility model will be further described in detail below through embodiments and in conjunction with the accompanying drawings.
[0019] Example: This example describes a thermal management system for a rescue station, such as... Figures 1 to 3As shown, the system includes a temperature controller 6, a water curtain mechanism 1, a water tank 2, heat dissipation pipes, and a water pump 3. The heat dissipation pipes include multiple heat exchange pipes 5 evenly laid on the upper surface of the rescue station and connected end to end. The inlet end of the heat dissipation pipes is connected to the outlet end of the water tank through the water pump 3. The water curtain mechanism includes a fan 11, a water distribution trough 12, a water curtain, and a water collection trough 13. The outlet end of the heat dissipation pipes is connected to the inlet end of the water distribution trough 12, the inlet end of the water curtain is connected to the outlet end of the water distribution trough 12, the outlet end of the water curtain is connected to the inlet end of the water collection trough 13, and the outlet end of the water collection trough 13 is connected to the inlet end of the water tank. The fan 11 is used to blow air onto the water curtain. The temperature controller 6 is electrically connected to the water pump. The temperature controller 6 is used to detect the temperature of the upper surface of the rescue station and control the operation of the water pump according to the temperature.
[0020] The water curtain includes multiple cooling columns 14 arranged side by side. The cooling columns 14 are vertically arranged and their bottom ends are fixedly connected to the water collection tank 13. The water distribution tank 12 is located above the cooling columns 14. The water distribution tank 12 is provided with water flow holes 121 corresponding to the positions of the cooling columns 14. The air outlet of the fan 11 is directly facing all the cooling columns 14.
[0021] The outer surface of the cooling column 14 is uniformly covered with uneven protrusions 141. The outer surface of the cooling column 14 is covered with a cooling sponge 15.
[0022] In this solution, when the temperature controller detects that the surface temperature of the rescue station has reached a preset value, it starts the water pump, which draws water from the water tank into the heat dissipation pipes. The water in the heat dissipation pipes absorbs the temperature drop on the surface of the rescue station, causing the surface temperature to decrease. The water in the heat dissipation pipes flows into the water distribution trough and then flows through the water outlets to the corresponding cooling columns, where it is absorbed by the cooling sponges. At the same time, the fan blows air onto the cooling columns and cooling sponges to cool the water. The cooled water then flows through the cooling sponges and cooling columns into the water collection tank, and then flows back into the water tank, completing the cycle. This solution is low in cost and low in energy consumption.
[0023] One type of rescue station in this embodiment, such as Figure 4 As shown, it includes a rest station box body and the aforementioned rest station heat dissipation system. The rest station box body 4 is made of a shipping container, and the heat dissipation pipes are installed on the upper surface of the rest station box body 4.
[0024] When the temperature controller detects that the temperature on the upper surface of the station box has reached the preset value, it controls the water pump to turn on and dissipate heat from the upper surface of the station box through the heat dissipation pipes.
Claims
1. A heat dissipation management system for a rescue station, characterized in that: The system includes a temperature controller (6), a water curtain mechanism (1), a water tank (2), a heat dissipation pipe, and a water pump (3). The heat dissipation pipe includes multiple heat exchange pipes (5) that are evenly laid on the top of the rescue station and connected end to end. The inlet end of the heat dissipation pipe is connected to the outlet end of the water tank through the water pump (3). The water curtain mechanism includes a fan (11), a water distribution trough (12), a water curtain, and a water collection trough (13). The outlet end of the heat dissipation pipe is connected to the inlet end of the water distribution trough (12). The inlet end of the water curtain is connected to the outlet end of the water distribution trough (12). The outlet end of the water curtain is connected to the inlet end of the water collection trough (13). The outlet end of the water collection trough (13) is connected to the inlet end of the water tank. The fan (11) is used to blow air onto the water curtain. The temperature controller (6) is electrically connected to the water pump. The temperature controller (6) is used to detect the temperature at the top of the rescue station and control the operation of the water pump according to the temperature.
2. The rescue station heat dissipation management system according to claim 1, characterized in that: The water curtain includes multiple cooling columns (14) arranged side by side. The cooling columns (14) are vertically arranged and their bottom ends are fixedly connected to the water collection tank (13). The water distribution tank (12) is located above the cooling columns (14). The water distribution tank (12) is provided with water flow holes (121) corresponding to the cooling columns (14). The air outlet of the fan (11) is directly facing all the cooling columns (14).
3. The rescue station heat dissipation management system according to claim 2, characterized in that: The outer surface of the cooling column (14) is uniformly distributed with uneven protrusions (141).
4. The rescue station heat dissipation management system according to claim 3, characterized in that: The outer surface of the cooling column (14) is wrapped with a cooling sponge (15).
5. A rescue station, characterized in that, The system includes a station container (4) and a rescue station heat dissipation management system as described in any one of claims 1-4, wherein the station container (4) is made of a shipping container and the heat dissipation pipes are located on the top of the station container (4).