CN104766274A - Method and device for rotating 3D energy consumption display model - Google Patents

Abstract

The invention discloses a method and a device for rotating a 3D energy consumption display model, and relates to the field of intelligent buildings. The display direction of a 3D energy consumption display model can be changed according to the demand of users, the problem that equipment blocks each other during display in a fixed direction and the experience effect is poor due to deviation in viewing angle is overcome, managers can conveniently observe the energy consumption situation of any piece of equipment, and the accuracy and efficiency of energy management are further improved. The method mainly comprises the following steps: establishing a 3D energy consumption display model and setting rotation parameters of each piece of model equipment in the 3D energy consumption display model; and acquiring the corresponding rotation parameters according to the demand of a user, and displaying the 3D energy consumption display model corresponding to the rotation parameters, wherein the rotation parameters include rotation position parameter and rotation direction parameter. The method and the device of the invention are mainly used in the process of rotary display of a 3D energy consumption model.

Description

A kind of 3D energy consumption shows spinning solution and the device of model

Technical field

The present invention relates to intelligent construction field, be specifically related to intelligent construction energy management field, particularly relate to spinning solution and device that a kind of 3D energy consumption shows model.

Background technology

Energy management system (Energy Management System, be called for short EMS) layered distribution type system architecture can be adopted, each classification such as electric power, combustion gas, water energy consumption data of building is gathered, processed, and analyze building energy consumption situation, thus realize the administration of energy conservation of building, have in modern intelligent building field and apply very widely.

Energy management system is combined with 3D modeling technique, just can realize the 3D of equipment energy consumption in building and show.With can only carry out compared with the two dimension traditional energy management system of showing to equipment state, the energy consumption of all devices that whole can be built by 3D energy management system is presented by solid, intuitively mode, optimize man-machine interaction mode, make supvr can locate the irrational place of energy for building quickly and accurately, so that revise the defect of current energy source operating strategy in time, improve energy management efficiency.

When performing above-mentioned energy management method, inventor finds that in prior art, at least there are the following problems: in 3D energy management system, always show with the energy consumption of constant bearing to equipment, but due to the many and spatial distribution differences of energy consumption main equipment quantity, probably occur mutually blocking between part energy consumption equipment under Orientation observation orientation and the situation of observer's angular deviation, make supvr cannot observe directly the running status of the energy consumption equipment that is blocked, thus the operation reserve of the equipment of being blocked can not be adjusted in time, experience effect is poor, affect the efficiency of energy management.

Summary of the invention

In view of this, the spinning solution that the embodiment of the present invention provides a kind of 3D energy consumption to show model and device, solve the technical matters that above background technology part is mentioned.

On the one hand, embodiments provide the spinning solution that a kind of 3D energy consumption shows model, described method comprises: after setting up 3D energy consumption displaying model, arrange the rotation parameter that described 3D energy consumption shows each simulator in model; The rotation parameter corresponding according to the Requirement Acquisition of user, and 3D energy consumption corresponding for described rotation parameter is shown that model is shown; Wherein, described rotation parameter comprises position of rotation parameter and sense of rotation parameter.

On the other hand, the embodiment of the present invention additionally provides the whirligig that a kind of 3D energy consumption shows model, and described device comprises: arrange module, for after setting up 3D energy consumption displaying model, arranges the rotation parameter that described 3D energy consumption shows each simulator in model; Rotary module, the described rotation parameter that module installation be set corresponding according to the Requirement Acquisition of user, and 3D energy consumption corresponding for described rotation parameter is shown that model is shown; Wherein, described rotation parameter comprises position of rotation parameter and sense of rotation parameter.

A kind of 3D energy consumption that the embodiment of the present invention proposes shows spinning solution and the device of model, by the rotation parameter of preset model equipment, then according to customer requirement retrieval rotation parameter, and described 3D energy consumption corresponding for described Selection parameter is shown model display out, supvr can be needed according to the observation, change the displaying orientation that described 3D energy consumption shows model, overcome equipment room under constant bearing mutually to block and due to the problem of viewing angle deviation experience effect difference, be conducive to supvr and make correct decisions by global information, further increase accuracy rate and the efficiency of energy management.

Accompanying drawing explanation

By reading the detailed description done non-limiting example done with reference to the following drawings, other features, objects and advantages of the present invention will become more obvious:

Fig. 1 is the spinning solution process flow diagram of a kind of 3D energy consumption displaying model that the specific embodiment of the invention provides;

Fig. 2 is that 3D energy consumption corresponding for described rotation parameter is shown that model carries out the method flow diagram shown by a kind of that the specific embodiment of the invention provides;

Fig. 3 is a kind of method flow diagram changing the observation visual angle of described 3D energy consumption displaying model according to described rotation parameter that the specific embodiment of the invention provides;

Fig. 4 is a kind of method flow diagram moving the observation place of described observation visual angle according to described position of rotation parameter that the specific embodiment of the invention provides;

Fig. 5 is a kind of method flow diagram rotating the direction of observation of described observation visual angle according to described sense of rotation parameter that the specific embodiment of the invention provides;

Fig. 6 is the spinning solution process flow diagram of the another kind of 3D energy consumption displaying model that the specific embodiment of the invention provides;

Fig. 7 is the spinning solution process flow diagram of another 3D energy consumption displaying model that the specific embodiment of the invention provides;

Fig. 8 is the composition frame chart of a kind of 3D energy consumption display systems that the specific embodiment of the invention provides.

Fig. 9 is the composition frame chart of the another kind of 3D energy consumption display systems that the specific embodiment of the invention provides.

Figure 10 is the composition frame chart of a kind of visual angle change submodule that the specific embodiment of the invention provides.

Figure 11 is the composition frame chart of the another kind of 3D energy consumption display systems that the specific embodiment of the invention provides.

Figure 12 is the composition frame chart of the another kind of 3D energy consumption display systems that the specific embodiment of the invention provides.

Embodiment

Below in conjunction with drawings and Examples, the present invention is described in further detail.Be understandable that, specific embodiment described herein is only for explaining the present invention, but not limitation of the invention.It also should be noted that, for convenience of description, illustrate only part related to the present invention in accompanying drawing but not full content.

The specific embodiment of the present invention, as shown in Figure 1, provide the spinning solution that a kind of 3D energy consumption shows model, the method comprises:

110, after setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set.

Wherein, described 3D energy consumption shows that model can be set up according to BIM BIM and physical device information.So-called BIM (Building Information Modeling is called for short BIM) is the basis using every relevant information data of construction-engineering project as model, carries out the foundation of BUILDINGS MODELS.By physical device information, BIM model is revised, just can obtain showing model with the on all four 3D energy consumption of the building situation of reality.

Described 3D energy consumption shows the device model including One's name is legion in model, each device model described 3D energy consumption show position in model and size different, therefore the best illustrated position of each equipment and angle are also different.In order to clearly show that described 3D energy consumption shows each simulator in model, first rotation parameter can be set for each simulator, for representing its best illustrated orientation.

Described rotation parameter can be determined by the empirical value of human eye, that is can by constantly adjusting self orientation of orientation and/or the described 3D energy consumption displaying model observing sight line, make human eye clearly can observe the correlation behavior of simulator and required details, now just can think the best illustrated position of described simulator, then the correlation parameter of this best illustrated position is recorded, just can as the rotation parameter of described simulator.Described rotation parameter also can be arranged according to the size of described simulator and position, specifically can show the size of model according to simulator and whole 3D energy consumption, arrange the viewing distance of simulator; According to the particular location of simulator in 3D energy consumption displaying model, the observation place of simulator is set; According to simulator 3D energy consumption show in model specifically towards, the direction of observation etc. of simulator is set, then these data is recorded, as described rotation rotation parameter.

Described rotation parameter can comprise position of rotation parameter and sense of rotation parameter, described position of rotation parameter may be used for describing the spatial relation that described observation place and 3D energy consumption show model, and described sense of rotation parameter may be used for describing the Spatial Direction Relations that described observation place and 3D energy consumption show model.

120, corresponding according to the Requirement Acquisition of user rotation parameter, and 3D energy consumption corresponding for described rotation parameter is shown that model is shown.

Particularly, during 3D models show, relate to model, observation visual angle and three-dimensional concept, carry out model to show the process that model scene observer can seen in virtual three-dimensional space in fact is exactly mapped to two-dimensional space.

When user needs specifically to check the display details of certain equipment in described 3D energy consumption displaying model, just first can obtain the rotation parameter of simulator to be shown, then according to described rotation parameter, only can change the observation visual angle that described 3D energy consumption shows model, also only can rotate described 3D energy consumption and show model itself, described 3D energy consumption can also be changed show the observation visual angle of model and rotate described 3D energy consumption and show model simultaneously, then will to have carried out above-mentioned observation visual angle and to have changed and/or postrotational described 3D energy consumption displaying model is shown.

A kind of 3D energy consumption that the embodiment of the present invention proposes shows the spinning solution of model, by the rotation parameter of preset model equipment, then according to customer requirement retrieval rotation parameter, and described 3D energy consumption corresponding for described Selection parameter is shown model display out, supvr can be needed according to the observation, change the displaying orientation that described 3D energy consumption shows model, overcome the problem that equipment room under constant bearing blocks mutually, be conducive to supvr and make correct decisions by global information, further increase accuracy rate and the efficiency of energy management.

Further, as shown in Figure 2, the specific embodiment of the present invention provides a kind of concrete grammar 3D energy consumption corresponding for described rotation parameter displaying model being carried out show, the method comprises:

210, according to described rotation parameter, the observation visual angle that described 3D energy consumption shows model is changed.

Particularly, described 3D energy consumption show model virtual three-dimensional space in be provided with virtual observer, the observed bearing of described observer can represent with observation visual angle.Described rotation parameter can represent the particular location of observer in virtual three-dimensional space, therefore, just can change the orientation of described observer according to described rotation parameter, be located at the particular location that described rotation parameter is specified, thus change the observation visual angle of described 3D energy consumption displaying model

220, the 3D energy consumption in the described observation visual angle after change is shown that model is shown.

Particularly, after the orientation of the observer in virtual three-dimensional space changes, the model scene can seen in its observation visual angle also can change, and the model scene after this change is exactly the part that user's needs of specifying carry out observing.Now, the 3D energy consumption in the observation visual angle after just observer orientation can being changed shows that Model Mapping is on computer screen curtain, checks for user is actual.

By 3D energy consumption corresponding for described rotation parameter, what the present embodiment proposed shows that model carries out the method for showing, when model is motionless, realizing the rotate effect of described 3D energy consumption displaying model by changing the observation visual angle of observer in virtual three-dimensional space, accurately can clearly show relevant device model.

Further, when described rotation parameter comprises position of rotation parameter and sense of rotation parameter, as shown in Figure 3, the specific embodiment of the present invention provides a kind of according to described rotation parameter, change the concrete grammar that described 3D energy consumption shows the observation visual angle of model, the method comprises:

310, according to described position of rotation parameter, the observation place of mobile described observation visual angle.

Wherein, the observation place of described observation visual angle can represent with the coordinate (x, y, z) in three dimensions, and described position of rotation parameter is also a volume coordinate (x ＇, y ＇, z ＇).So, the observation place of described observation visual angle is moved according to described position of rotation parameter, in other words by the observation place of observation visual angle from (x, y, z) (x ＇, y ＇, z ＇) point is moved to, first its concrete moving process can regulate described observation place and 3D energy consumption to show the distance of model, and then moves on the sphere being the center of circle with the center of described 3D energy consumption displaying model; Also first can move on the sphere being the center of circle with the center of described 3D energy consumption displaying model, and then regulate described observation place and 3D energy consumption to show the distance of model; Regulating described observation place and 3D energy consumption show the distance of model while, the sphere being the center of circle with the center of described 3D energy consumption displaying model can also be moved, the position finally making described observation visual angle reach described position of rotation parameter to specify.

320, according to described sense of rotation parameter, the direction of observation of described observation visual angle is rotated.

Described sense of rotation parameter can be a vector, and it represents the direction of observation of described observation visual angle in virtual three dimensional space.Because the observation place of described observation visual angle changes, its direction of observation is affected and no longer may shows model facing to described 3D energy consumption, just cannot carry out model views.And according to described sense of rotation parameter, the direction of observation rotating described observation visual angle just can guarantee that the direction of observation of described observation visual angle shows model towards described 3D energy consumption forever, so that follow-up, simulator is shown.

It should be noted that, the observation place of mobile described observation visual angle and these two steps of direction of observation of the described observation visual angle of rotation do not have sequencing, can carry out simultaneously yet.Because described position of rotation parameter and described sense of rotation parameter all pre-set, no matter how process operates, as long as the most described observation visual angle changes to the two specified orientation, just can realize the spinfunction that described 3D energy consumption shows model.

Further, as shown in Figure 4, the specific embodiment of the present invention additionally provides a kind of according to described position of rotation parameter, the concrete grammar of the observation place of mobile described observation visual angle, and the method comprises:

311, according to the translational speed of described observation place and the display frame number of described 3D energy consumption displaying model, the moving step length of described observation place is determined.

Wherein, described display frame number refers to the amount of the picture transmitted in 1 seconds, also can be understood as graphic process unit and can refresh several times p.s..Each frame is all static image, and in extremely rapid succession display frame just defines the illusion of motion.Usually, when display frame number per second is greater than 24, human eye just can obtain smooth animated image.

Therefore, in order to the rotate effect smoothness true to nature making described 3D energy consumption show model, the display frame number of model can be shown according to the translational speed of described observation place and described 3D energy consumption, determine the moving step length of described observation place.If the translational speed of described observation place in virtual three-dimensional space is 1m/s, described 3D energy consumption shows that the display frame number of model is 30 frames/s, so just can determine that the moving step length of described observation place is 1/30m.It will be appreciated by those skilled in the art that; above-mentioned concrete translational speed and display frame number do not limit the scope of the invention; no matter be that translational speed and display frame number are specifically how many, as long as the moving step length determined according to translational speed and display frame number, all in protection scope of the present invention.

312, according to described moving step length, progressively move described observation place, and the 3D energy consumption in the described observation visual angle after at every turn mobile is shown that model is shown.

Particularly, when described observation visual angle being moved to the concrete coordinate points that described position of rotation parameter specifies, if be directly position of rotation parameter by observation place parameter modification, then can cause beating of display frame, thus cause lacking of the dizzy of user and direction feeling.Therefore the present embodiment adopts according to described moving step length, the mode progressively moving described observation place changes observation place gradually, and the 3D energy consumption in the described observation visual angle after at every turn mobile is shown that model is shown, such that display frame is progressively level and smooth from existing position is transitioned into position to be seen.

Further, as shown in Figure 5, the specific embodiment of the present invention provides a kind of according to described sense of rotation parameter, and rotate the concrete grammar of the direction of observation of described observation visual angle, the method comprises:

321, according to the rotational speed of described direction of observation and the display frame number of described 3D energy consumption displaying model, the rotary step of described direction of observation is determined.

The movement of its ultimate principle and above observation place is similar, can show the display frame number of model, determine the rotary step of described direction of observation according to the rotational speed of described direction of observation and described 3D energy consumption.If the translational speed of described observation place in virtual three-dimensional space is 5 °/s, described 3D energy consumption shows that the display frame number of model is 30 frames/s, so just can determine that the rotary step of described direction of observation is 1/6 °.It will be appreciated by those skilled in the art that; above-mentioned concrete rotational speed and display frame number do not limit the scope of the invention; no matter be that rotational speed and display frame number are specifically how many, as long as the rotary step determined according to rotational speed and display frame number, all in protection scope of the present invention.

322, according to described rotary step, progressively rotate described direction of observation, and the 3D energy consumption in each postrotational described observation visual angle is shown that model is shown.

Particularly, when described observation visual angle being rotated to the concrete direction of specifying in described position of rotation direction, if be directly sense of rotation parameter by direction of observation parameter modification, then can cause beating of display frame, thus cause the disappearance of the dizzy of user and direction feeling.Therefore the present embodiment adopts according to described rotary step, the mode progressively rotating described direction of observation changes direction of observation gradually, and the 3D energy consumption in each postrotational described observation visual angle is shown that model is shown, such that display frame is progressively level and smooth from existing direction is transitioned into direction to be seen.

The method changing the observation visual angle of described 3D energy consumption displaying model according to described rotation parameter that the embodiment of the present invention proposes, the observation visual angle of 3D energy consumption displaying model is changed by the method progressively moving observation place and rotational view direction, achieve 3D energy consumption and show that model rotates to the function of demand position gradually, reach the display effect of smooth Smooth Rotation, avoid the sense of discomfort that user produces due to picture sudden change.

Further, as shown in Figure 6, the specific embodiment of the present invention provides the concrete spinning solution that another kind of 3D energy consumption shows model, and the method comprises:

410, after setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set.

Wherein, described rotation parameter can comprise modal position parameter and model direction parameter, represents each simulator respectively when best illustrated, and 3D energy consumption shows position and the direction of model self.

420, corresponding according to the Requirement Acquisition of user rotation parameter, then according to described rotation parameter, rotates described 3D energy consumption and shows model.

Particularly, the simulator observed is needed according to user, obtain corresponding rotation parameter, then rotate described 3D energy consumption according to rotation parameter and show model, namely move the position of described 3D energy consumption displaying model according to modal position parameter, and rotate the direction of described 3D energy consumption displaying model according to model direction parameter.

430, the described 3D energy consumption through rotating is shown that model is shown.

Particularly, postrotational described 3D energy consumption is shown that model is shown, namely user needed the correlative detail of the simulator observed to show, facilitate user to check.

Further, as shown in Figure 7, the specific embodiment of the present invention provides the concrete spinning solution that another 3D energy consumption shows model, and the method comprises:

510, after setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set.

Wherein, described rotation parameter can represent the position relation between described 3D energy consumption displaying model and described observation visual angle.

520, corresponding according to the Requirement Acquisition of user rotation parameter, then according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model, and rotates described 3D energy consumption displaying model simultaneously.

Particularly, obtain the rotation parameter of user's request, because described rotation parameter can define the position relation between described 3D energy consumption displaying model and described observation visual angle, therefore can change described 3D energy consumption simultaneously and show that the observation of model rotates described 3D energy consumption and shows model when treating as, position relation is therebetween adjusted to the position relation that described rotation parameter is specified.

530, the 3D energy consumption through rotating in the described observation visual angle after change is shown that model is shown.

Particularly, observation visual angle and 3D energy consumption show that the orientation of model all there occurs change, the 3D energy consumption through rotating in the described observation visual angle after change being shown that model is shown, just obtaining the simulator details that user needs to check.

Two kinds of 3D energy consumptions that above-mentioned two embodiments of the present invention propose show the spinning solution of model, pass through rotating model, or the mode changing observation visual angle achieves the rotational display of 3D energy consumption displaying model simultaneously, make user that can concrete rotation mode be set according to demand, improve dirigibility and applicability that 3D energy consumption shows model spinning solution.

As shown in Figure 8, the specific embodiment of the present invention provides a kind of 3D energy consumption to show the whirligig of model, and this device comprises: arrange module 61 and rotary module 62.

Module 61 is set, for after setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set.

By 3D energy consumption corresponding for described rotation parameter, rotary module 62, for the described rotation parameter that arrange module 61 arrange corresponding according to the Requirement Acquisition of user, and shows that model is shown.

Wherein, described rotation parameter comprises position of rotation parameter and sense of rotation parameter.

Further, as shown in Figure 9, described rotary module 62 comprises: visual angle changes submodule 621 and first and shows submodule 622.

Visual angle changes submodule 621, for according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model.

First shows submodule 622, for described visual angle is changed submodule 621 change after described observation visual angle in 3D energy consumption show that model is shown.

Further, as shown in Figure 10, described visual angle change submodule 621 comprises: position mobile unit 71 and direction rotary unit 72.

Position mobile unit 71, for according to described position of rotation parameter, moves the observation place of described observation visual angle.

Direction rotary unit 72, for according to described sense of rotation parameter, rotates the direction of observation of described observation visual angle.

Further, as shown in Figure 10, described position mobile unit 71 comprises: moving step length determination subelement 711 and progressively Mobile exhibiting subelement 712.

Moving step length determination subelement 711, for according to the translational speed of described observation place and the display frame number of described 3D energy consumption displaying model, determines the moving step length of described observation place.

Progressively Mobile exhibiting subelement 712, for the described moving step length determined according to described moving step length determination subelement 711, progressively moves described observation place, and the 3D energy consumption in the described observation visual angle after at every turn mobile is shown that model is shown.

Further, as shown in Figure 10, described direction rotary unit 72 comprises: rotary step determination subelement 721 and progressively rotary display subelement 722.

Rotary step determination subelement 721, for according to the rotational speed of described direction of observation and the display frame number of described 3D energy consumption displaying model, determines the rotary step of described direction of observation.

Progressively rotary display subelement 722, for the described rotary step determined according to described rotary step determination subelement 721, progressively rotates described direction of observation, and the 3D energy consumption in each postrotational described observation visual angle is shown that model is shown.

Further, as shown in figure 11, described rotary module 62 comprises: model gyrator module 623 and second shows submodule 624.

Model gyrator module 623, for according to described rotation parameter, rotates described 3D energy consumption and shows model.

Second shows submodule 624, for the described 3D energy consumption rotated through described model gyrator module is shown that model is shown.

Further, as shown in figure 12, described rotary module 62 comprises: dual change submodule 625 and the 3rd shows submodule 626.

Dual change submodule 625, for according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model, and rotates described 3D energy consumption displaying model simultaneously;

3rd shows submodule 626, for the 3D energy consumption through rotating in the described observation visual angle after change is shown that model is shown.

The above; be only the specific embodiment of the present invention, but protection scope of the present invention is not limited thereto, is anyly familiar with those skilled in the art in the technical scope that the present invention discloses; change can be expected easily or replace, all should be encompassed within protection scope of the present invention.Therefore, protection scope of the present invention should described be as the criterion with the protection domain of claim.

Claims (14)

1. 3D energy consumption shows a spinning solution for model, and it is characterized in that, described method comprises:

After setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set;

The rotation parameter corresponding according to the Requirement Acquisition of user, and 3D energy consumption corresponding for described rotation parameter is shown that model is shown;

Wherein, described rotation parameter comprises position of rotation parameter and sense of rotation parameter.

2. 3D energy consumption according to claim 1 shows the spinning solution of model, it is characterized in that, described 3D energy consumption corresponding for described rotation parameter is shown that model is shown, comprising:

According to described rotation parameter, change the observation visual angle that described 3D energy consumption shows model;

3D energy consumption in described observation visual angle after change is shown that model is shown.

3. 3D energy consumption according to claim 2 shows the spinning solution of model, it is characterized in that, described according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model, comprising:

According to described position of rotation parameter, the observation place of mobile described observation visual angle;

According to described sense of rotation parameter, rotate the direction of observation of described observation visual angle.

4. 3D energy consumption according to claim 3 shows the spinning solution of model, it is characterized in that, described according to described position of rotation parameter, and the observation place of mobile described observation visual angle, comprising:

According to the translational speed of described observation place and the display frame number of described 3D energy consumption displaying model, determine the moving step length of described observation place;

According to described moving step length, progressively move described observation place, and the 3D energy consumption in the described observation visual angle after at every turn mobile is shown that model is shown.

5. 3D energy consumption according to claim 3 shows the spinning solution of model, it is characterized in that, described according to described sense of rotation parameter, rotates the direction of observation of described observation visual angle, comprising:

According to the rotational speed of described direction of observation and the display frame number of described 3D energy consumption displaying model, determine the rotary step of described direction of observation;

According to described rotary step, progressively rotate described direction of observation, and the 3D energy consumption in each postrotational described observation visual angle is shown that model is shown.

6. 3D energy consumption according to claim 1 shows the spinning solution of model, it is characterized in that, described 3D energy consumption corresponding for described rotation parameter is shown that model is shown, comprising:

According to described rotation parameter, rotate described 3D energy consumption and show model;

Described 3D energy consumption through rotating is shown that model is shown.

7. 3D energy consumption according to claim 1 shows the spinning solution of model, it is characterized in that, described 3D energy consumption corresponding for described rotation parameter is shown that model is shown, comprising:

According to described rotation parameter, change the observation visual angle that described 3D energy consumption shows model, and rotate described 3D energy consumption displaying model simultaneously;

3D energy consumption through rotating in described observation visual angle after change is shown that model is shown.

8. 3D energy consumption shows a whirligig for model, and it is characterized in that, described device comprises:

Module is set, for after setting up 3D energy consumption displaying model, the rotation parameter that described 3D energy consumption shows each simulator in model is set;

By 3D energy consumption corresponding for described rotation parameter, rotary module, for the described rotation parameter that arrange module installation corresponding according to the Requirement Acquisition of user, and shows that model is shown;

Wherein, described rotation parameter comprises position of rotation parameter and sense of rotation parameter.

9. 3D energy consumption according to claim 8 shows the whirligig of model, and it is characterized in that, described rotary module comprises:

Visual angle changes submodule, for according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model;

First shows submodule, for the 3D energy consumption in the described observation visual angle after the change of described visual angle change submodule is shown that model is shown.

10. 3D energy consumption according to claim 9 shows the whirligig of model, and it is characterized in that, described rotation parameter comprises position of rotation parameter and sense of rotation parameter, and described visual angle changes submodule and comprises:

Position mobile unit, for according to described position of rotation parameter, moves the observation place of described observation visual angle;

Direction rotary unit, for according to described sense of rotation parameter, rotates the direction of observation of described observation visual angle.

11. 3D energy consumptions according to claim 10 show the whirligig of model, and it is characterized in that, described position mobile unit comprises:

Moving step length determination subelement, for according to the translational speed of described observation place and the display frame number of described 3D energy consumption displaying model, determines the moving step length of described observation place;

Progressively Mobile exhibiting subelement, for the described moving step length determined according to described moving step length determination subelement, progressively moves described observation place, and the 3D energy consumption in the described observation visual angle after at every turn mobile is shown that model is shown.

12. 3D energy consumptions according to claim 10 show the whirligig of model, and it is characterized in that, described direction rotary unit comprises:

Rotary step determination subelement, for according to the rotational speed of described direction of observation and the display frame number of described 3D energy consumption displaying model, determines the rotary step of described direction of observation;

Progressively rotary display subelement, for the described rotary step determined according to described rotary step determination subelement, progressively rotates described direction of observation, and the 3D energy consumption in each postrotational described observation visual angle is shown that model is shown.

13. 3D energy consumptions according to claim 8 show the whirligig of model, and it is characterized in that, described rotary module comprises:

Model gyrator module, for according to described rotation parameter, rotates described 3D energy consumption and shows model;

Second shows submodule, for the described 3D energy consumption rotated through described model gyrator module is shown that model is shown.

14. 3D energy consumptions according to claim 8 show the spinning solution of models, it is characterized in that, described 3D energy consumption corresponding for described rotation parameter are shown that model is shown, comprising:

Dual change submodule, for according to described rotation parameter, changes the observation visual angle that described 3D energy consumption shows model, and rotates described 3D energy consumption displaying model simultaneously;

3rd shows submodule, for the 3D energy consumption through rotating in the described observation visual angle after change is shown that model is shown.