CN-224203660-U - Cooling distribution device

Abstract

The utility model relates to a cooling distribution device which comprises a first heat exchange end and a second heat exchange end, wherein the first heat exchange end is provided with a first cold water end and a first warm water end, the first cold water end and the first warm water end are communicated with a heat dissipation device, the first heat exchange end is connected with the second heat exchange end to conduct heat exchange, the second heat exchange end is provided with a second cold water end and a second warm water end, the second cold water end and the second warm water end are communicated with a heating device to take out heat, the second cold water end is provided with a water outlet pipe, an adapter, a water inlet pipe and an electrode rod, one end of the water outlet pipe is communicated with the first end of the adapter, the second end of the adapter is communicated with the water inlet pipe, one end of the water inlet pipe is communicated with the heating device, and the adapter is provided with an opening part, and the electrode rod is inserted into the opening part and is fixed on the adapter so that cooling water can flow smoothly.

Inventors

• ZHANG YUXIU

Assignees

• 兴亚太节能科技股份有限公司

Dates

Publication Date

20260505

Application Date

20250604

Claims (4)

1. 1. The cooling distribution device comprises a first heat exchange end and a second heat exchange end, wherein the first heat exchange end is provided with a first cold water end and a first warm water end which are communicated with a heat dissipation device, the first heat exchange end is connected with the second heat exchange end for heat exchange, the second heat exchange end is provided with a second cold water end and a second warm water end, and the second cold water end and the second warm water end are communicated with a heating device, and the cooling distribution device is characterized in that: The second cold water end is provided with a water outlet pipe, an adapter, a water inlet pipe and an electrode rod, one end of the water outlet pipe is communicated with the first end of the adapter, the second end of the adapter is communicated with the water inlet pipe, one end of the water inlet pipe is communicated with the heating device, and the adapter is provided with an opening part, and the electrode rod is inserted into the opening part and fixed on the adapter.
2. 2. The cooling distribution device according to claim 1, further comprising a first reducer and a second reducer, wherein the small diameter end of the first reducer is connected to one end of the water outlet pipe, the large diameter end of the first reducer is connected to the first end of the adapter, the small diameter end of the second reducer is connected to the other end of the water inlet pipe, and the large diameter end of the second reducer is connected to the second end of the adapter.
3. 3. The cooling distribution device according to claim 1 or 2, wherein the electrode rod comprises a ceramic housing and a cable, the ceramic housing is inserted into the opening and accommodated in the water outlet pipe, one end of the cable is inserted into and fixed in the ceramic housing, and the other end of the cable is electrically connected to a power supply for inputting a direct current of high voltage and low current.
4. 4. The cooling distribution device according to claim 1 or 2, wherein the electrode rod comprises a ceramic housing and a cable, the ceramic housing is inserted into the opening and accommodated in the water inlet pipe, one end of the cable is inserted into and fixed to the inside of the ceramic housing, and the other end of the cable is electrically connected to a power supply for inputting a direct current of high voltage and low current.

Description

Cooling distribution device Technical Field The present utility model relates to a cooling distribution device, and more particularly, to a cooling distribution device capable of effectively preventing biofilm formation, inhibiting bacterial growth and bacterial scaling, and further enabling a cooling water flow to be smooth. Background The heat dissipation and Cooling system of the existing computer data processing center is mainly divided into four areas sequentially, wherein the 1 st area is a high-temperature load heat source area (Loading) with continuously increased power consumption, the 2 nd area is a liquid Cooling and Cooling distribution area of a Cooling and distributing device (CDU, coolant distribution unit), the 3 rd area is a Cooling area of a plate heat exchange (PLATE HEAT exchange) or an ice water machine (Chillers), and the 4 th area of the final stage is a total heat dissipation area for dissipating all heat by using a Cooling tower (Cooling tower). The data in the Server (Server) in zone 1 is processed and calculated mainly by a plurality of Central Processing Units (CPUs), and the plurality of central processing units are mostly heat sinks of the type closely attached to the Cold plates (Cold plates), and then heat dissipation is performed by the heat exchange effect of the fluid in the micro flow channels inside the Cold plates. However, because the channels of the micro-channels are very narrow, when the cooling water flow in each area cannot smoothly flow, especially when the cooling water flow entering the 1 st area from the cooling distribution device contains tiny particles, oxides and impurities, or scales and biological films are bred and blocked in the water flow pipeline, the heat conduction capacity of each radiator is reduced, the overall cooling efficiency is reduced, and the operating efficiency of a computer is further reduced. Disclosure of utility model In view of this, the present utility model has been made in order to provide a structure different from the prior art and to improve the above-mentioned drawbacks, and the experience of the creator for many years and the continuous development and improvement. The cooling distributor includes one first heat exchange end with one first cold water end and one first warm water end connected to one heat radiator, one second heat exchange end with one second cold water end and one second warm water end connected to one heat generator, one water outlet pipe, one adapter with one end connected to the first end of the adapter and one end connected to the water inlet pipe, one heating unit, and one electrode rod inserted into the opening and fixed onto the adapter. When in implementation, the utility model further comprises a first reducing pipe and a second reducing pipe, wherein the small diameter end of the first reducing pipe is communicated with one end of the water outlet pipe, the large diameter end of the first reducing pipe is communicated with the first end of the adapter, the small diameter end of the second reducing pipe is communicated with the other end of the water inlet pipe, and the large diameter end of the second reducing pipe is communicated with the second end of the adapter. When the electrode rod is implemented, the electrode rod comprises a ceramic shell and a cable conductor, the ceramic shell is inserted into the opening part and is accommodated in the water outlet pipe, one end of the cable conductor is inserted into and fixed in the ceramic shell, and the other end of the cable conductor is electrically connected with a power supply for inputting high-voltage and low-current direct current. When the electrode rod is implemented, the electrode rod comprises a ceramic shell and a cable conductor, the ceramic shell is inserted into the opening and is accommodated in the water inlet pipe, one end of the cable conductor is inserted into and fixed in the ceramic shell, and the other end of the cable conductor is electrically connected with a power supply for inputting high-voltage and low-current direct current. The cooling distribution device has the beneficial effects that the cooling distribution device can solve the problems that the cooling water flow of the existing cooling system cannot smoothly flow and dissipate heat in the micro-flow channel in the cold plate, the heat conduction capacity can be reduced, the overall cooling efficiency is reduced, and the running efficiency of a computer is further reduced, and the electrode bar structure is arranged at the bent pipe at the cold water outlet end of the cooling distribution device, so that the generation of a biomembrane is prevented, the growth of bacteria and the generation of bacterial scaling substances are inhibited, the cooling water flow is smooth, the heat dissipation capacity is not reduced, the stable running of computer operation is further ensured, and the electricity cost and the energy are also effectively saved. Drawings FIG. 1 is a