CN102003774A - Indoor temperature control method of train air-conditioner - Google Patents

Abstract

The invention discloses an indoor temperature control method of a train, which is applicable to the technical field of air-conditioning equipment of a rail transportation vehicle. The method comprises the following steps: under an automatic running mode of an air-conditioner, firstly calculating a difference value between setting temperature and outdoor temperature; setting the air-conditioner to run for a period of time at a certain gear according to the range of the difference value, and calculating a difference value between indoor temperature and the setting temperature; and judging whether the air-conditioner is subject to refrigerating or heating conversion towards a higher stage or lower stage according to the range of the difference value. The method has the following beneficial effects: (1) the indoor temperature of the train is closer to the setting temperature without wide fluctuation so that a driver and passengers in the train feel more comfortable; and (2) refrigerating or heating is adjusted step by step according to the difference value between the indoor temperature and the setting temperature owing to influence of the outdoor temperature, thus avoiding unnecessary energy waste and being more economical and environmental-friendly.

Description

Train air-conditioning indoor temperature control method

Technical field

The present invention relates to a kind of air conditioning chamber method for controlling temperature inner, especially a kind of train air-conditioning indoor temperature control methods of can many grades regulating refrigerating capacity or heating capacity are applicable to the rail traffic vehicles air conditioner technical field.

Background technology

Along with the fast development of China's rail transit train and comprehensive operation of EMU, people are also more and more higher for the requirement of air quality in vehicle and comfort level, and the air-conditioning equipment that is used to regulate the train room air becomes the emphasis of research gradually.Train air-conditioning indoor temperature control method in the past is: running state of air conditioner depends on the deviation size of design temperature and indoor temperature, and indoor temperature is higher than design temperature, then air conditioner refrigerating; Indoor temperature is lower than design temperature, and then air-conditioning system is warm; Indoor temperature and design temperature are suitable, air conditioner ventilation.Such establishing method can make indoor temperature change with the variation of design temperature really, but, for space comparatively narrow and small drivers' cab or refrigerating capacity or the bigger air-conditioning system of heating capacity, refrigeration or the warm startup of system can make indoor temperature turn cold apace or warm, cause the indoor temperature scope to surpass design temperature, thereby need to start once more the warm or refrigerating operaton of system.Cause indoor temperature frequently to fluctuate widely easily like this, also cause the waste of the energy.

Summary of the invention

The technical problem to be solved in the present invention provides a kind of train air-conditioning indoor temperature control method that can prevent that the train indoor temperature fluctuates excessive with each grade of air-conditioning status adjustment.

For solving the problems of the technologies described above, the technical solution used in the present invention is:

The inventive method step is as follows:

Step 1, start moves air-conditioning automatically;

Step 2 is judged the current operational mode of air-conditioning, when air-conditioning need transfer non-automatic operational mode to, and EP (end of program), otherwise carry out next step;

Step 3 judges whether the sensor of air-conditioning is normal, and when sensor fault, program changes fault mode over to and handles, otherwise carries out next step;

Step 4, a given design temperature t _s, at outdoor temperature t _oWith design temperature t _sUnder the normal situation, calculate design temperature t _sWith outdoor temperature t _oDifference DELTA t _oWhenever resetting a design temperature t _sThe time, need recomputate Δ t _o

Step 5, the given first difference temperature t ₁, the second difference temperature t ₂With the 3rd difference temperature t ₃, the described first difference temperature t ₁Less than the second difference temperature t ₂, the described second difference temperature t ₂Less than the 3rd difference temperature t ₃, then according to Δ t _oSpan, adjust the running status of air-conditioning:

(1) as Δ t _o≤ t ₁The time, temperature t in the counting chamber _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₃The time, the full cold state of operation of air conditioner 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₁The time, air-conditioning continues the full cold state of operation;

2. as Δ t _i≤ t ₁The time, operation of air conditioner half cold state;

(2) as Δ t _i≤ t ₃The time, operation of air conditioner half cold state 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₂The time, the full cold state of operation of air conditioner;

2. work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues operation half cold state;

3. as Δ t _i≤ t ₁The time, the operation of air conditioner ventilation state;

(2) work as t ₁＜Δ t _o≤ t ₃The time, operation of air conditioner ventilation state 3 minutes, temperature t in the counting chamber then _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₂The time, operation of air conditioner half cold state;

(2) work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the operation ventilation state;

(3) as Δ t _i≤ t ₁The time, operation of air conditioner first order system warms up state;

(3) as Δ t _o＞t ₃The time, the warm state of operation of air conditioner first order system 3 minutes, temperature t in the counting chamber then _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₂The time, the operation of air conditioner ventilation state;

(2) work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the warm state of operation first order system;

(3) as Δ t _i≤ t ₁The time, the warm state of operation of air conditioner second level system 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₂The time, operation of air conditioner first order system warms up state;

2. work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the warm state of operation second level system;

3. as Δ t _i≤ t ₁The time, the warm full state of operation of air conditioner 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

A, as Δ t _i＞t ₂The time, operation of air conditioner second level system warms up state;

B, as Δ t _i≤ t ₂The time, air-conditioning continues the complete warm state of operation.

The described first difference temperature t ₁Best value be-2 ℃, the described second difference temperature t ₂Best value be 2 ℃, described the 3rd difference temperature t ₃Best value be 5 ℃.

Beneficial effect of the present invention is as follows:

(1) can make the train indoor temperature more level off to design temperature, can fluctuatedly not fluctuate widely, make that the driver and conductor feels that comfortableness is better in the car.

(2) influence of consideration outdoor temperature, according to the difference of indoor temperature and design temperature, adjusting refrigeration step by step or system are warm, have avoided the unnecessary waste of the energy, environmental protection more economically.

Description of drawings

The present invention is further detailed explanation below in conjunction with the drawings and specific embodiments.

Fig. 1 is a program flow diagram of the present invention.

The specific embodiment

As shown in Figure 1, performing step of the present invention is as follows:

Step 1, start moves air-conditioning automatically;

Step 2 is judged the current operational mode of air-conditioning, in the time of need transferring non-automatic operational mode such as forced service pattern to when air-conditioning, and EP (end of program), otherwise carry out next step;

Step 3 judges whether the sensor of air-conditioning is normal, and when sensor fault, program changes fault mode over to and handles, otherwise carries out next step;

Step 4, a given design temperature t _s, at outdoor temperature and design temperature t _sUnder the normal situation, calculate design temperature t _sWith outdoor temperature t _oDifference DELTA t _oWhenever resetting a design temperature t _sThe time, need recomputate Δ t _o

Step 5,5 ℃ of the given first difference temperature-2 ℃, 2 ℃ of the second difference temperature and the 3rd difference temperature are then according to Δ t _oSpan, adjust the running status of air-conditioning:

(1) as Δ t _oIn the time of≤-2 ℃, temperature t in the counting chamber _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _iIn the time of＞5 ℃, show indoor temperature far above design temperature, at this moment the full cold state of operation of air conditioner continues to recomputate indoor temperature t after 3 minutes _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _iIn the time of＞-2 ℃, show indoor temperature still far above design temperature, at this moment air-conditioning continues the full cold state of operation;

2. as Δ t _iIn the time of≤-2 ℃, show that indoor temperature near design temperature, no longer needs excessive refrigerating capacity, in order to avoid the low excessively situation of temperature occurs, air-conditioning redirect at this moment moves half cold state;

(2) as Δ t _iIn the time of≤5 ℃, show that indoor temperature is higher than design temperature, but be not that refrigerating capacity mutually far short of what is expected, too high causes that easily indoor temperature reduces fast that it is uncomfortable that the occupant feels, at this moment allow operation of air conditioner half cold state 3 minutes, recomputate indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _iIn the time of＞2 ℃, show that half cold state can't make indoor temperature reduce, air-conditioning need be adjusted to the upper level refrigeration, at this moment allows the full cold state of operation of air conditioner;

2. as-2 ℃＜Δ t _iIn the time of≤2 ℃, it is consistent with design temperature to show that the operation of half cold state can be kept indoor temperature substantially, and refrigerating capacity is crossed conference and caused that indoor temperature is low excessively, and the too small meeting of refrigerating capacity causes that indoor temperature uprises, and at this moment allows air-conditioning continue operation half cold state;

3. as Δ t _iIn the time of≤-2 ℃, show that indoor temperature reduces too much, refrigerating capacity is bigger than normal, at this moment allows air-conditioning jump to the operation ventilation state;

(2) as-2 ℃＜Δ t _oIn the time of≤5 ℃, show that outdoor temperature and design temperature are suitable, air-conditioning only needs to move ventilation state, makes room air mix with outdoor air, and indoor temperature and design temperature reach unanimity, and at this moment allows operation of air conditioner ventilation state 3 minutes, then temperature t in the counting chamber _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _iIn the time of＞2 ℃, show that ventilation state can't be that indoor temperature reduces, air-conditioning need be adjusted to the upper level refrigerating state, at this moment allows operation of air conditioner half cold state;

(2) as-2 ℃＜Δ t _iIn the time of≤2 ℃, it is consistent with design temperature to show that ventilation state can be kept indoor temperature substantially, and refrigeration can cause that indoor temperature is low excessively, and system is warm can to cause that indoor temperature uprises, and at this moment allows air-conditioning continue the operation ventilation state;

(3) as Δ t _iIn the time of≤-2 ℃, show that indoor temperature reduces too much, at this moment allow air-conditioning jump to the warm state of operation first order system;

(3) as Δ t _oIn the time of＞5 ℃, much relations are arranged owing to making the warm operation and the safety of vehicle, thus the warm increase step by step of system, avoid the too high heating capacity that causes of initial launch state excessive, cause potential safety hazard.At this moment allow operation of air conditioner first order system warm up state 3 minutes, then temperature t in the counting chamber _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _iIn the time of＞2 ℃, show that the operation of the warm state of first order system is risen too much indoor temperature, at this moment allow air-conditioning to the next stage adjustment, the operation ventilation state;

(2) as-2 ℃＜Δ t _iIn the time of≤2 ℃, it is consistent with design temperature that the operation that shows the warm state of first order system can be kept indoor temperature substantially, and ventilation state can cause that indoor temperature is low excessively, and second level system is warm can to cause that indoor temperature is too high, at this moment allows air-conditioning continue operation first order system and warms up state;

(3) as Δ t _iIn the time of≤-2 ℃, show that the variation of indoor temperature can not be satisfied the requirement of design temperature under the warm state of first order system, at this moment allow operation of air conditioner second level system warm up state 3 minutes, recomputate indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _iIn the time of＞2 ℃, show that the operation of the warm state of second level system is risen too much indoor temperature, at this moment allow air-conditioning whole, the warm state of the first order system of promptly moving to next stage system warm color tone;

2. as-2 ℃＜Δ t _iIn the time of≤2 ℃, it is consistent with design temperature that the operation that shows the warm state of second level system can be kept indoor temperature substantially, reduces heating capacity and can cause that indoor temperature is low excessively, increases heating capacity and can cause that indoor temperature is too high, at this moment allows air-conditioning continue operation second level system and warm up state;

3. as Δ t _iIn the time of≤-2 ℃, show that the variation of indoor temperature can not be satisfied the requirement of design temperature under the warm state of second level system, at this moment allow air-conditioning jump to the complete warm state of operation, continue to recomputate indoor temperature t after 3 minutes _iWith design temperature t _sDifference DELTA t _i

A, as Δ t _iIn the time of＞2 ℃, show that the operation of complete warm state is risen too much indoor temperature, at this moment allow air-conditioning whole, the warm state of the second level system of promptly moving to next stage system warm color tone;

B, as Δ t _iIn the time of≤2 ℃, it is consistent with design temperature to show that full operation of warming up state can be kept indoor temperature substantially, reduces heating capacity and can cause that indoor temperature is low excessively, at this moment allows air-conditioning continue the full state that warms up of operation.

Illustrate below in conjunction with a specific embodiment how method of the present invention realizes:

The indoor temperature control of Siemens X4 project adopts method of the present invention to realize.Design temperature be 18 ℃ to 26 ℃ adjustable, operational mode is chosen as automatically.

After the start, detect the difference DELTA t of design temperature and outdoor temperature _oDifference DELTA t with indoor temperature and design temperature _i, as Δ t _o≤-2 ℃ and Δ t _iIn the time of＞5 ℃, air-conditioning is carried out 680 refrigerating states, i.e. the full carrying row of refrigeration system.After moving 3 minutes under this state, if Δ t _i＞-2 ℃, then air-conditioning continues to carry out 680 refrigerating states; If Δ t _i≤-2 ℃, then air-conditioning is carried out 450 refrigerating states.

Air-conditioning is after moving 3 minutes under 450 refrigerating states, if Δ t _i＞2 ℃, operation of air conditioner 680 refrigerating states then; If-2 ℃＜Δ t _i≤ 2 ℃, then air-conditioning continues operation 450 refrigerating states; If Δ t _i≤-2 ℃, operation of air conditioner ventilation state then.

Air-conditioning moves 3 minutes under ventilation state after, if Δ t _i＞2 ℃, operation of air conditioner 450 refrigerating states then; If-2 ℃＜Δ t _i≤ 2 ℃, then air-conditioning continues the operation ventilation state; If Δ t _i≤-2 ℃, then operation of air conditioner 2.8KW system warms up state.

Air-conditioning is after moving 3 minutes under the warm state of 2.8KW system, if Δ t _i＞2 ℃, operation of air conditioner ventilation state then; If-2 ℃＜Δ t _i≤ 2 ℃, then air-conditioning continues the warm state of operation 2.8KW system; If Δ t _i≤-2 ℃, then operation of air conditioner 4.7 KW systems warm up state.

Air-conditioning is after moving 3 minutes under the warm state of 4.7 KW systems, if Δ t _i＞2 ℃, then operation of air conditioner 2.8KW system warms up state, if-2 ℃＜Δ t _i≤ 2 ℃, then air-conditioning continues the warm state of operation 4.7 KW systems; If Δ t _i≤-2 ℃ and start detect Δ t _o＞45 ℃, then the warm state of operation of air conditioner 7 KW systems warms up state otherwise continue operation 4.7 KW systems.

In sum, train air-conditioning indoor temperature control method provided by the invention can make air-conditioning more comfortable to the control of vehicle interior temperature, has avoided air conditioner refrigerating, has made the frequent transitions between warming up, and has prolonged the service life of air-conditioning; Cooling/heating is regulated step by step simultaneously, has also avoided the waste of the energy, more economically environmental protection.

Claims (2)

1. train indoor temperature control method is characterized in that its method step is as follows:

Step 1, start moves air-conditioning automatically;

Step 2 is judged the current operational mode of air-conditioning, when air-conditioning need transfer non-automatic operational mode to, and EP (end of program), otherwise carry out next step;

Step 3 judges whether the sensor of air-conditioning is normal, and when sensor fault, program changes fault mode over to and handles, otherwise carries out next step;

Step 4, a given design temperature t _s, at outdoor temperature t _oWith design temperature t _sUnder the normal situation, calculate design temperature t _sWith outdoor temperature t _oDifference DELTA t _oWhenever resetting a design temperature t _sThe time, need recomputate Δ t _o

Step 5, the given first difference temperature t ₁, the second difference temperature t ₂With the 3rd difference temperature t ₃, the described first difference temperature t ₁Less than the second difference temperature t ₂, the described second difference temperature t ₂Less than the 3rd difference temperature t ₃, then according to Δ t _oSpan, adjust the running status of air-conditioning:

(1) as Δ t _o≤ t ₁The time, temperature t in the counting chamber _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₃The time, the full cold state of operation of air conditioner 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₁The time, air-conditioning continues the full cold state of operation;

2. as Δ t _i≤ t ₁The time, operation of air conditioner half cold state;

(2) as Δ t _i≤ t ₃The time, operation of air conditioner half cold state 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₂The time, the full cold state of operation of air conditioner;

2. work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues operation half cold state;

3. as Δ t _i≤ t ₁The time, the operation of air conditioner ventilation state;

(2) work as t ₁＜Δ t _o≤ t ₃The time, operation of air conditioner ventilation state 3 minutes, temperature t in the counting chamber then _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₂The time, operation of air conditioner half cold state;

(2) work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the operation ventilation state;

(3) as Δ t _i≤ t ₁The time, operation of air conditioner first order system warms up state;

(3) as Δ t _o＞t ₃The time, the warm state of operation of air conditioner first order system 3 minutes, temperature t in the counting chamber then _iWith design temperature t _sDifference DELTA t _i

(1) as Δ t _i＞t ₂The time, the operation of air conditioner ventilation state;

(2) work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the warm state of operation first order system;

(3) as Δ t _i≤ t ₁The time, the warm state of operation of air conditioner second level system 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

1. as Δ t _i＞t ₂The time, operation of air conditioner first order system warms up state;

2. work as t ₁＜Δ t _i≤ t ₂The time, air-conditioning continues the warm state of operation second level system;

3. as Δ t _i≤ t ₁The time, the warm full state of operation of air conditioner 3 minutes recomputates indoor temperature t then _iWith design temperature t _sDifference DELTA t _i

A, as Δ t _i＞t ₂The time, operation of air conditioner second level system warms up state;

B, as Δ t _i≤ t ₂The time, air-conditioning continues the complete warm state of operation.

2. train indoor temperature control method according to claim 1 is characterized in that the described first difference temperature t ₁Best value be-2 ℃, the described second difference temperature t ₂Best value be 2 ℃, described the 3rd difference temperature t ₃Best value be 5 ℃.