CN104864573A - Heating and ventilation self-control system for data center - Google Patents

Abstract

The invention provides a heating and ventilation self-control system for a data center. The heating and ventilation self-control system for the data center comprises a cold water subsystem, a tail air conditioning subsystem, an on-site environment detection subsystem and a heating and ventilation self-control subsystem, wherein the cold water subsystem is used for controlling cooling water of the data center, the tail air conditioning subsystem is used for refrigerating the data center, the on-site environment detection subsystem is used for detecting the on-site environment of the data center to generate detection parameters, and the heating and ventilation self-control subsystem is used for managing heating and ventilation devices of the data center and uniformly managing the cold water subsystem, the tail air conditioning subsystem and the on-site environment detection subsystem according to running parameters of the cold water subsystem, running parameters of the tail air conditioning subsystem and the detection parameters. The heating and ventilation self-control system for the data center can effectively improve intelligent refrigeration effects.

Description

For the HVAC robot control system(RCS) of data center

Technical field

The present invention relates to air-conditioning technical field, particularly relate to a kind of HVAC robot control system(RCS) for data center.

Background technology

Along with the high speed development of cloud calculation service, the scale of data center is increasing, system complexity constantly increases, energy resource consumption is increasing, huge challenge is proposed to the efficient cooling of data center, particularly in the face of huge garden scale, the automation of HVAC system, intelligent operation degree are had higher requirement.

In correlation technique, for the HVAC inter-autonomous system of data center without communication, isolated operation, what cannot realize between system is collaborative, and efficiency of energy utilization is low, and intelligent operational effect is poor.

Summary of the invention

The present invention is intended to solve one of technical problem in correlation technique at least to a certain extent.

For this reason, the object of the invention is to propose a kind of HVAC robot control system(RCS) for data center, this HVAC robot control system(RCS) being used for data center can effectively improve intelligent refrigeration.

For achieving the above object, the HVAC robot control system(RCS) for data center that the embodiment of the present invention proposes, comprise: cold water subsystem, tail end air conditioner subsystem, site environment detection subsystem, and HVAC is from control subsystem, wherein, described cold water subsystem, for controlling the cooling water of described data center, and is sent to described HVAC from control subsystem by the operational factor of described cold water subsystem; Described tail end air conditioner subsystem, for freezing to described data center, and is sent to described HVAC from control subsystem by the operational factor of described tail end air conditioner subsystem; Described site environment detection subsystem, for detecting the site environment of described data center and generating detected parameters, and is sent to described HVAC from control subsystem by described detected parameters; Described HVAC is from control subsystem, for managing the heating and ventilating equipment of described data center, and according to the operational factor of described cold water subsystem, the operational factor of described tail end air conditioner subsystem and described detected parameters, unified management is carried out to described cold water subsystem, described tail end air conditioner subsystem and described site environment detection subsystem.

The HVAC robot control system(RCS) for data center that the embodiment of the present invention proposes, by managing the heating and ventilating equipment of described data center, and according to the operational factor of described cold water subsystem, the operational factor of described tail end air conditioner subsystem and described detected parameters, unified management is carried out to described cold water subsystem, described tail end air conditioner subsystem and described site environment detection subsystem, effectively improve intelligent refrigeration.

The aspect that the present invention adds and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present invention.

Accompanying drawing explanation

The present invention above-mentioned and/or additional aspect and advantage will become obvious and easy understand from the following description of the accompanying drawings of embodiments, wherein:

Fig. 1 is the structural representation of the HVAC robot control system(RCS) for data center that one embodiment of the invention proposes.

Detailed description of the invention

Be described below in detail embodiments of the invention, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Being exemplary below by the embodiment be described with reference to the drawings, only for explaining the present invention, and can not limitation of the present invention being interpreted as.On the contrary, embodiments of the invention comprise fall into attached claims spirit and intension within the scope of all changes, amendment and equivalent.

Fig. 1 is the structural representation of the HVAC robot control system(RCS) for data center that one embodiment of the invention proposes, and this system 10 comprises cold water subsystem 11, tail end air conditioner subsystem 12, site environment detection subsystem 13, and HVAC is from control subsystem 14.

The operational factor of described cold water subsystem 11 for controlling the cooling water of described data center, and is sent to described HVAC from control subsystem 14 by described cold water subsystem 11.

The operational factor of described tail end air conditioner subsystem 12 for freezing to described data center, and is sent to described HVAC from control subsystem 14 by described tail end air conditioner subsystem 12.

Described detected parameters for detecting the site environment of described data center and generating detected parameters, and is sent to described HVAC from control subsystem 14 by described site environment detection subsystem 13.

Described HVAC for managing the heating and ventilating equipment of described data center, and carries out unified management according to the operational factor of described cold water subsystem 11, the operational factor of described tail end air conditioner subsystem 12 and described detected parameters to described cold water subsystem 11, described tail end air conditioner subsystem 12 and described site environment detection subsystem 13 from control subsystem 14.

Optionally, HVAC robot control system(RCS) 14 can adopt easily extensible programming Control system, manages the heating and ventilating equipment of described data center.

Particularly, HVAC passes through direct digital controller (Direct Digital Control from control subsystem 14, DDC)/programmable logic controller (PLC) (Programmable Logic Controller, PLC) control the overhead coil pipe of cold water subsystem 11, tail end air conditioner subsystem 12, OCU124, and controlled by DDC/PLC or Precision Integrated air-conditioning 122, air-conditioning 123 between row.

Wherein, see Fig. 1, described cold water subsystem 11 coordinates cooling tower 111, cold-storage tank 112, cold 113 and water circle device 114.

Optionally, described tail end air conditioner subsystem 12 comprises air-conditioning 123 between air-conditioner set 121, precision air conditioner 122, row, and OCU124.

Optionally, described site environment detection subsystem 13 comprises temperature data checkout gear 131, humidity data checkout gear 132, pressure data checkout gear 133, and air quality data detection device 134.

In an embodiment, described HVAC from control subsystem 14 specifically for monitoring the operational factor of described tail end air conditioner subsystem 12 and described detected parameters, and the operational factor of described tail end air conditioner subsystem 12 and described detected parameters are sent to described cold water subsystem 11, adjust the control strategy of described cold 113 correspondence to make described cold water subsystem 11 according to cold control logic.

In another embodiment, the described HVAC robot control system(RCS) for data center also comprises communication interface 15, for described HVAC from the communication between control subsystem 14, described cold water subsystem 11, tail end air conditioner subsystem 12, site environment detection subsystem 13.

Particularly, HVAC, from the reserved communication interface of docking with between cold water subsystem 11, tail end air conditioner subsystem 12, site environment detection subsystem 13 of control subsystem 14, transmits and interlock with the data realized between each subsystem.

Such as, HVAC gathers the information such as air-supply, return air, rotation speed of fan of tail end air conditioner subsystem 12 by controller from control subsystem 14, calculate the situation of cold 113 load, by control system internal communication, be transferred to cold controller, cold controller, by calculating, draws the optimum operation pattern of cold 113, and regulates and controls accordingly.Because load according to regulation and control constantly change, can constantly can be carried out so this regulates and controls action in real time.It is the key ensureing these regulation and control that tail end air conditioner subsystem 12 and cold 113 include unified control system in.

Again such as, HVAC gathers the information such as machine room environment temperature, humidity, carbon dioxide from control subsystem 14 by controller, calculate the situation of air conditioner load in tail end air conditioner subsystem 12, by control system internal communication, be transferred to the controller in tail end air conditioner subsystem 12, tail end air conditioner controller, by calculating, draws the optimum operation pattern of air-conditioning, and regulates and controls accordingly.Because load according to regulation and control constantly change, can constantly can be carried out so this regulates and controls action in real time.It is the key ensureing these regulation and control that parameter in site environment detection subsystem 13 and tail end air conditioner subsystem 12 include unified control system in.

In the present embodiment, by managing the heating and ventilating equipment of described data center, and according to the operational factor of described cold water subsystem, the operational factor of described tail end air conditioner subsystem and described detected parameters, unified management is carried out to described cold water subsystem, described tail end air conditioner subsystem and described site environment detection subsystem, effectively improve intelligent refrigeration.

It should be noted that, in describing the invention, term " first ", " second " etc. only for describing object, and can not be interpreted as instruction or hint relative importance.In addition, in describing the invention, except as otherwise noted, the implication of " multiple " is two or more.

Describe and can be understood in flow chart or in this any process otherwise described or method, represent and comprise one or more for realizing the module of the code of the executable instruction of the step of specific logical function or process, fragment or part, and the scope of the preferred embodiment of the present invention comprises other realization, wherein can not according to order that is shown or that discuss, comprise according to involved function by the mode while of basic or by contrary order, carry out n-back test, this should understand by embodiments of the invention person of ordinary skill in the field.

Should be appreciated that each several part of the present invention can realize with hardware, software, firmware or their combination.In the above-described embodiment, multiple step or method can with to store in memory and the software performed by suitable instruction execution system or firmware realize.Such as, if realized with hardware, the same in another embodiment, can realize by any one in following technology well known in the art or their combination: the discrete logic with the logic gates for realizing logic function to data-signal, there is the special IC of suitable combinational logic gate circuit, programmable gate array (PGA), field programmable gate array (FPGA) etc.

Those skilled in the art are appreciated that realizing all or part of step that above-described embodiment method carries is that the hardware that can carry out instruction relevant by program completes, described program can be stored in a kind of computer-readable recording medium, this program perform time, step comprising embodiment of the method one or a combination set of.

In addition, each functional unit in each embodiment of the present invention can be integrated in a processing module, also can be that the independent physics of unit exists, also can be integrated in a module by two or more unit.Above-mentioned integrated module both can adopt the form of hardware to realize, and the form of software function module also can be adopted to realize.If described integrated module using the form of software function module realize and as independently production marketing or use time, also can be stored in a computer read/write memory medium.

The above-mentioned storage medium mentioned can be read-only storage, disk or CD etc.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present invention or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and describe embodiments of the invention above, be understandable that, above-described embodiment is exemplary, can not be interpreted as limitation of the present invention, and those of ordinary skill in the art can change above-described embodiment within the scope of the invention, revises, replace and modification.

Claims (6)

1. for a HVAC robot control system(RCS) for data center, it is characterized in that, comprise cold water subsystem, tail end air conditioner subsystem, site environment detection subsystem, and HVAC is from control subsystem, wherein,

Described cold water subsystem, for controlling the cooling water of described data center, and is sent to described HVAC from control subsystem by the operational factor of described cold water subsystem;

Described tail end air conditioner subsystem, for freezing to described data center, and is sent to described HVAC from control subsystem by the operational factor of described tail end air conditioner subsystem;

Described site environment detection subsystem, for detecting the site environment of described data center and generating detected parameters, and is sent to described HVAC from control subsystem by described detected parameters;

Described HVAC is from control subsystem, for managing the heating and ventilating equipment of described data center, and according to the operational factor of described cold water subsystem, the operational factor of described tail end air conditioner subsystem and described detected parameters, unified management is carried out to described cold water subsystem, described tail end air conditioner subsystem and described site environment detection subsystem.

2. the HVAC robot control system(RCS) for data center according to claim 1, is characterized in that, described cold water subsystem coordinates cooling tower, cold-storage tank, cold and water circle device.

3. the HVAC robot control system(RCS) for data center according to claim 1, is characterized in that, described tail end air conditioner subsystem comprises air-conditioning between air-conditioner set, precision air conditioner, row, and OCU.

4. the HVAC robot control system(RCS) for data center according to claim 1, it is characterized in that, described site environment detection subsystem comprises temperature data checkout gear, humidity data checkout gear, pressure data checkout gear, and air quality data detection device.

5. the HVAC robot control system(RCS) for data center according to claim 2, is characterized in that, described HVAC from control subsystem specifically for:

Monitor the operational factor of described tail end air conditioner subsystem and described detected parameters, and the operational factor of described tail end air conditioner subsystem and described detected parameters are sent to described cold water subsystem, adjust control strategy corresponding to described cold to make described cold water subsystem according to cold control logic.

6. the HVAC robot control system(RCS) for data center according to any one of claim 1-5, it is characterized in that, also comprise: be connected to described HVAC from the communication interface between control subsystem, described cold water subsystem, tail end air conditioner subsystem, site environment detection subsystem.