CN201016939Y

CN201016939Y - Direction error-correcting equipment and mobile radiation checking system

Info

Publication number: CN201016939Y
Application number: CNU2007201036627U
Authority: CN
Inventors: 许西宁; 孙尚民; 杨中荣; 彭华; 杨光; ***; 栗志军
Original assignee: Qinghua Tongfang Weishi Tech Co Ltd
Current assignee: Tongfang visual technology Limited by Share Ltd; Tsinghua University
Priority date: 2007-02-16
Filing date: 2007-02-16
Publication date: 2008-02-06
Anticipated expiration: 2017-02-16

Abstract

Direction rectification equipment used in a movable radiation inspection system is provided. The movable radiation inspection system includes a moving device. The direction rectification equipment includes a direction detection device, which detects the moving direction of the moving device and produces detection signals indicating the moving direction, a direction control device which controls the moving direction of the moving device and a control unit. The control unit calculates a deviation value between a moving direction and a predetermined direction according to the detection signals received from the direction control device. And the control unit drives the direction control device to correct the moving direction to the predetermined direction according to the deviation value. According to the direction rectification equipment of the utility model, the movable radiation inspection system can be automatically controlled to run straightly along the predetermined direction when working. The automatic control degree is improved. And the utility model has the advantages of simple structure, convenient installation and disassembly and low cost. And the normal run of the inspection system on a road during the inspection period can not be affected.

Description

Direction correcting device and mobile radiation checkout system

Technical field

The utility model relates to a kind of mobile radiation checkout system and is used for its direction correcting device.Especially, the utility model relates to and utilizes ray to being examined target imaging so that they are carried out the vehicle-mounted removable radiation checking system of radiation monitoring such as container/goods carrying vehicle etc.; The direction correcting device that is used for described vehicle-mounted removable radiation checking system, wherein when the moving direction depart of the mobile device of described mobile radiation checkout system, described direction correcting device automatically is corrected to described moving direction on the described predetermined direction.

Background technology

Be used to check that it is the essential checkout facility in customs, Civil Aviation Airport and railway station that container/goods carrying vehicle etc. is examined the vehicle-mounted removable radiation checking system that target checks.Described vehicle-mounted removable radiation checking system utilizes the principle of radiant image, under the situation of not opening container and goods carrying vehicle, by container/goods carrying vehicle is scanned, obtain the fluoroscopy images of the goods in container/goods carrying vehicle, through to graphical analysis, just can find to be hidden in the suspicious or prohibited items in the goods.

Mobile container/goods carrying vehicle check system is integrated on the chassis usually, and thus, described mobile radiation checkout system is also referred to as scanning car or vehicle-mounted removable radiation checking system usually, and described chassis is as the mobile device of check system.When checking work, checked container/goods carrying vehicle is parked in the zone to be checked of appointment, by scanning car it is scanned.Scanning car scanning process in along be parallel to be examined container/goods carrying vehicle predetermined direction along straight reciprocating motion.

Yet, owing to reason such as scanning car weight distribution inequality, ground injustice, air pressure be inconsistent, scanning car scan several times its moving direction of back may parallel deviate in the predetermined direction that is examined container/goods carrying vehicle, as the deviation in driction of untimely correction scanning car, the accident that bumps against with checked container/goods carrying vehicle may take place.

For departing from of correct scan car moving direction, traditional mobile container/goods carrying vehicle check system shuttle-scanning several times after, need stop scanning, by operating personnel the moving direction of scanning car is corrected on the predetermined direction, this has influenced the work efficiency of system greatly.

In addition, for departing from of correct scan car moving direction, special driver is arranged in the pilothouse of scanning car, the driver corrects the moving direction of scanning car in scanning process, yet this has increased human cost.There is the scattering of ray during simultaneously owing to scanning, therefore can injures the healthy of driver.

The utility model content

The utility model is intended to solve at least in part problems of the prior art, automatic direction correcting device according to the vehicle-mounted removable radiation checking system of the utility model embodiment, do not need artificial participation just can control mobile radiation checkout system automatically and when work, keep linear running along predetermined direction, the automatic control degree of raising system, the utility model is simple in structure, installation, convenient disassembly, cost is low, and does not influence the travelling on road of mobile radiation checkout system.

Correspondingly, according to first aspect of the present utility model, a kind of direction correcting device that is used for mobile radiation checkout system is proposed, described mobile radiation checkout system comprises mobile device, described direction correcting device comprises: direction detection device, described direction detection device detect the moving direction of described mobile device and produce the detection signal of the described moving direction of indication; Direction-control apparatus, described direction-control apparatus is used to control the moving direction of described mobile device; And control module, described control module calculates deviation value between moving direction and the predetermined direction according to the detection signal that receives from described direction detection device, and according to described deviation value driving direction control device so that described moving direction is corrected on the predetermined direction.

Preferably, described direction detection device comprises first and second distance detectors, described first and second distance detectors produce the first and second distance detecting signals respectively, and wherein said control module is according to the described deviation value of the first and second distance detecting calculated signals.

And then described first and second distance detectors detect described mobile device to first and second distances that are examined target.

Preferably, described direction correcting device further comprises reference component, and wherein said first and second distance detectors detect first distance and the second distance of described mobile device to described reference component.

Preferably, described first and second distance detectors comprise laser range sensor.

Preferably, described control module comprises: analog/digital converter, and described analog/digital converter is a digital signal with the described first and second distance detecting signal from analog conversion of signals; Processor, described processor goes out described deviation value so that produce the drive signal corresponding with deviation value according to the first and second distance detecting calculated signals that are converted to digital signal; Signal driver, described signal driver reception also increases described drive signal; And driving circuit, described driving circuit is according to the drive direction-control apparatus of the increase that receives from signal driver, so that proofread and correct the moving direction of mobile device.

And then described control module further comprises signal isolator, and described signal isolator is connected between the input of the output of analog/digital converter and processor, is used to isolate the input signal that is input to it and from the output signal of its output.

And then described signal isolator comprises photoisolator.

Preferably, described processor comprises single-chip microcomputer.

Preferably, described direction-control apparatus comprises: the bearing circle of the moving direction of control mobile device; And actuator, described actuator engages separably with described bearing circle and is driven by control module, thus so that the driving direction dish rotates the moving direction of control mobile device.

And then described direction-control apparatus further comprises bindiny mechanism, and an end of described bindiny mechanism links to each other with actuator and the other end engages separably with the bearing circle of mobile device.

Particularly, described bindiny mechanism comprises: connecting link, and an end of described connecting link links to each other with actuator; Pillar, the other end of described connecting link links to each other with described pillar by oscillating bearing, and is provided with the nut that is used for positioning link bar on the top of pillar; Installing plate, described pillar is installed on the end face of installing plate, and the side of described installing plate joins on the neighboring of bearing circle separably so that the driving direction dish rotates.

And then described direction-control apparatus further comprises support and cross piece, and wherein said cross piece and support are hinged so that form universal joint, and described actuator is installed on the support by the cross piece.

Particularly, described direction-control apparatus further comprises: back up pad, described support are installed on the described back up pad; Protection switch, described Protection switch are installed on the described back up pad; And pressing plate, described pressing plate is connected on the described universal joint, and when breaking away from bearing circle together with convenient actuator and bindiny mechanism, described pressing plate crash switch is so that make the actuator outage.

Preferably, wherein said actuator comprises: motor, and described motor is driven by described control module; Worm gear, described worm gear links to each other with the output shaft of described motor; And worm screw, described worm screw and the engagement of described worm gear, and the axial end of described worm screw is connected with described bindiny mechanism.

Preferably, described actuator comprises hydraulic cylinder, and described hydraulic cylinder is driven by described control module and its cylinder bar links to each other with described bindiny mechanism.

And then described actuator comprises cylinder, and described cylinder is driven by described control module and its cylinder bar links to each other with described bindiny mechanism.

Alternatively, described direction-control apparatus comprises: gearing, and described gearing is driven by described control module; And flexible traction piece, the two ends of described flexible traction piece are walked around bearing circle and are connected respectively on the gearing.

And then described flexible traction piece is a traction rope.

Preferably, described traction rope is bonded on separably by clamp and screw in the groove of excircle of bearing circle.

Preferably, described gearing comprises: by the motor of control module driving; With by motor-driven double output shaft speed reduction unit, the two ends of described traction rope link to each other with two output shafts of double output shaft speed reduction unit respectively.

Preferably, described gearing further comprises: first and second shaft couplings, the input side of first and second shaft couplings link to each other with two output shafts of described speed reduction unit respectively; The first and second rolling wheel axles, the described first and second rolling wheel axles link to each other with the outgoing side of first and second shaft couplings respectively and are supported by first and second supporting seats respectively; With first and second rolling wheels, described first and second rolling wheels are respectively installed on the first and second rolling wheel axles, and the two ends of wherein said traction rope are wrapped in respectively on first and second rolling wheels.

And then described gearing further comprises first and second regulating devices, and described first and second regulating devices are used to regulate the rate of tension of described traction rope.

And then described gearing further comprises first and second overrunning clutches that are separately positioned in first and second shaft couplings.

Preferably, described overrunning clutch comprises internal tooth ratchet overrunning clutch.

In addition, described reference component comprises the flat part of the one that be arranged in parallel with described predetermined direction.

Alternatively, described reference component comprises a plurality of flat plate section, and described a plurality of flat plate section are spaced apart from each other on described predetermined direction and arrange alignedly.

Preferably, described direction detection device comprises at least one optoelectronic switch, and wherein said control module is controlled at preset distance according to the signal that receives from described at least one optoelectronic switch with described mobile device and the described distance that is examined between the target.

Preferably, optoelectronic switch is two.

Preferably, described control module comprises: the signal picker transmitter is used to gather the signal of described first and second distance detectors and described optoelectronic switch; And signal receiver, be used for the described signal that wireless receiving sends from described data acquisition unit transmitter.

According to second aspect of the present utility model, a kind of mobile radiation checkout system is proposed, comprise according to the described direction correcting device of the utility model first aspect.

According to the automatic direction correcting device of the utility model and use their mobile radiation checkout system, when the moving direction depart of mobile system, control module is according to the deviation value between detected detection signal calculating moving direction and the predetermined direction, and based on the deviation value driving direction control device that calculates, thereby the moving direction of mobile device is corrected on the predetermined direction, makes mobile device move along straight line in a predetermined direction.

Therefore, when orientation departs from, do not need to stop the operation of check system, and do not need personnel's participation, control module is finished correction for direction automatically, has improved work efficiency and security performance, and simple in structure, and installation and removal are convenient, and cost is low.

In addition, according to preferred embodiment of the present utility model, by two optoelectronic switches are set, can with mobile device and be examined target such as the container vehicle between distance be controlled to be predetermined distance, thereby prevent from mobile device with respect to being examined the target translation and collide to be examined target.

Description of drawings

Fig. 1 is the schematic diagram according to the direction correcting device that is used for mobile radiation checkout system of the utility model first embodiment;

Fig. 2 is the vertical view that illustrates according to the duty of direction correcting device of the present utility model, wherein shows first embodiment of reference component;

Fig. 3 is the vertical view that illustrates according to the duty of direction correcting device of the present utility model, wherein shows second embodiment of reference component;

Fig. 4 is the synoptic diagram according to the direction correcting device of the utility model second embodiment;

Fig. 5 is that it is in running order wherein to show direction-control apparatus according to the structural representation of the direction-control apparatus of the utility model first embodiment;

Fig. 6 is the schematic top plan view of direction-control apparatus shown in Figure 5;

Fig. 7 is the enlarged diagram of part shown in the mark C among Fig. 5;

Fig. 8 is the structural representation that direction-control apparatus shown in Figure 5 is in off working state, and wherein the actuator of direction-control apparatus separates with bearing circle;

Fig. 9 is the structural representation according to the direction-control apparatus of the utility model second embodiment;

Figure 10 is the schematic top plan view after direction-control apparatus shown in Figure 9 clockwise rotates 90 degree;

Figure 11 is the structural representation of the gearing of direction-control apparatus shown in Figure 9;

Figure 12 is the schematic top plan view of gearing shown in Figure 11;

Figure 13 is the principle schematic according to the signal isolator of the utility model embodiment;

Figure 14 is the circuit diagram according to the signal driver of the utility model embodiment;

Figure 15 is the process flow diagram according to the direction correcting method of the utility model embodiment.

Embodiment

Describe embodiment of the present utility model below in detail, the example of described embodiment is shown in the drawings, and wherein identical from start to finish label is represented components identical.So that explain the utility model, described embodiment is exemplary, and can not be interpreted as restriction of the present utility model below by embodiment is described with reference to the drawings.

Fig. 1 is for according to the schematic diagram that is used for the direction correcting device 100 of mobile radiation checkout system 7 of the present utility model, and Fig. 2 shows the in running order vertical view of direction correcting device 100.

In embodiment of the present utility model, mobile radiation checkout system 7 comprises mobile device 5, and described mobile device 5 drives whole check system 7 and moves.In other words, the ingredient of check system 7, radiation source for example, detector, imaging control system etc. all are arranged on the mobile device 5, and described mobile device 5 for example can adopt the chassis motor vehicle of sole (as have).Therefore, described portable the inspection is 7 to be commonly referred to scanning car or vehicle-mounted removable radiation checking system.

Yet, need to prove that the mobile device 5 of mobile radiation checkout system 7 is not limited to chassis, can be any suitable mobile device in this area, for example can be the trailer that drags by motor vehicle or other draw-gears.

Shown in Fig. 1-2, the correcting device that is used for mobile radiation checkout system 100 according to the utility model embodiment comprises reference component 1, as the first distance detector 2a and the second distance detecting device 2b of direction detection device, direction-control apparatus 4 and control module 3.

The first and

second distance detector

2a and 2b are arranged on the mobile device 5 of scanning car, and spaced apart preset distance L on the moving direction A of scanning car is used for first distance L 1 between detection reference parts 1 and the mobile device 5 and second distance L1 so that produce the first and second distance detecting signals.The first and

second distance detector

2a and 2b include but not limited to laser range sensor, and described laser range sensor sends laser to reference component 1, thereby measure first and second distance L 1 and the L2 between mobile device 5 and the reference component 1.

In the embodiment shown in Fig. 1 and Fig. 2, the first and

second range sensor

2a and 2b are the preferred implementations of direction detection device.Yet, described direction detection device is not limited to above-mentioned first and second range sensor 2a and the 2b, can comprise the moving direction that can detect mobile device 5 and can produce indication mobile device 5 moving direction detection signal and described detection signal is sent to any suitable device of control module 3, for example, a distance detector can only be set, also can realize correcting the deviation in driction of mobile device.

Direction-control apparatus 4 is used to control the moving direction of mobile device 5.Control module 3 receives the first and second distance detecting signals from the first and

second distance detector

2a and 2b, and go out deviation value between described moving direction A and the predetermined direction B according to the first and second distance detecting calculated signals, and then according to the deviation value driving direction control device 4 that calculates so that described moving direction A is corrected on the predetermined direction B, described predetermined direction for example be with as being examined the direction of the longitudinal center's parallel axes that is examined vehicle 6 of target.

In the embodiment shown in Fig. 2, reference component 1 is the flat type of one, and parallel being arranged on is examined the left side of vehicle 6.To during being examined vehicle 6 and checking, scanning car 7 is by reference component 1 and be examined between the vehicle 6, thereby measure first and second distance L 1 and the L2 from the laser real-time ground that the first and

second distance detector

2a and 2b send, and the consequent first and second distance detecting signals are sent to control module 3.

In embodiment illustrated in figures 1 and 2, the first and

second distance detector

2a and 2b are sent to control module 3 by cable with the first and second distance detecting signals.Alternatively, the described first and second distance detecting signals also can send to control module 3 (below will describe in detail) by Wireless transmission mode.

Alternatively, the reference component 1 of flat type also can be arranged on the right side that is examined vehicle 6, to during being examined vehicle 6 and checking, scanning car 7 moves in the left side that is examined vehicle 6, at this moment, the height of reference component 1 should be able to guarantee that can be examined vehicle 6 from the laser that the first and

second distance detector

2a and 2b send stops and arrive reference component 1.Certainly, reference component 1 also can be set directly at and is examined on the vehicle 6.

Alternatively, reference component 1 is not the essential parts of correcting device, for example, and can be by detecting mobile device 5 and being examined the purpose that distance between the vehicle 6 realizes detecting the moving direction of mobile device 5, that is to say, be examined vehicle 6 and can replace the reference component 1 of setting separately.Being appreciated that reference component 1 also can be arranged on is examined on the vehicle 6.

Need to prove that the length of reference component 1 usually should be greater than the moving area of scanning car 7, thereby during whole scanography, can both guarantee to be stopped by reference component 1 from the laser that the first and

second distance detector

2a and 2b send.

As shown in Figure 3, wherein show another embodiment of reference component 1, in the embodiment show in figure 3, reference component 1 is the form of a plurality of flat plate section, for example figure 3 illustrates 4 flat plate section 1a-1d, but the utility model is not limited to this, flat plate section can be any suitable quantity.Described four flat plate section 1a-1d are parallel to the isolated arrangement of described predetermined direction B and are in alignment with each other.

As shown in Figure 1, preferred, control module 3 comprises A/D converter (analog/digital converter) 8, processor 9, signal driver 11 and the driving circuit 12 that links to each other with 2b by cable and the first and second distance detector 2a.Preferred, control module 3 also comprises signal isolator 9.

The first and second distance detecting signal from analog conversion of signals that A/D converter 8 is used for coming from the first and

second distance detector

2a and 2b are digital signal, and the first and second distance detecting signals of digital signal form are sent to signal isolator 9.

As shown in figure 13, show an embodiment of signal isolator 9.Among the embodiment shown in Figure 13, signal isolator 9 is a photoisolator, and this photoisolator 9 is with light media transmission electric signal.9 pairs of described photoisolators are input to its input signal and from the output electric signal of its output the good isolation effect are arranged.Photoisolator 9 generally is made up of three parts: the emission of light, the reception of light and signal amplify, and the input and output side at light is respectively arranged with the first power supply VCC1 and second source VCC2, and the first power supply VCC1 links to each other with photoisolator 9 with R2 by first and second resistance R 1 respectively with second source VCC2.Input signal driven for emitting lights diode (LED), make it to send the light of certain wavelength, described light is received by photo-detector and produces photocurrent, again through further amplifying back output, thereby finish the conversion of " electrical-optical-", play the buffer action of input, output thus.Owing to isolate mutually between the input and output of photoisolator 9, its electric signal transmission has characteristics such as one-way, thereby has good electrical isolation capabilities and antijamming capability.

In the utility model, signal isolator 9 can adopt any appropriate signal isolator that can buy from the market, and is not limited to above-mentioned photoisolator.

Photoisolator 9 receives the digital distance detection signals from A/D converter 8, and with described signal through electrical-optical-" conversion after be sent to processor 10.

According to the utility model, processor 10 can be single-chip microcomputer, chip, programmable logic controller (PLC) (PLC), computing machine, or any other suitable treating apparatus.Processor 10 receives the first and second distance detecting signals from photoisolator 9, and go out the moving direction A of mobile device 5 (being scanning car 7) and the deviation value between the predetermined direction B according to the first and second distance detecting calculated signals, produce the drive signal corresponding thus with deviation value.

For example, if deviation value is zero, then processor 10 is determined moving direction A consistent with predetermined direction B (parallel), if deviation value is non-vanishing, then exist between processor 10 definite moving direction A and the predetermined direction B and depart from (that is, having certain included angle between moving direction A and the predetermined direction B).

For example, if deviation value be on the occasion of, then processor 10 determines that moving direction A depart from Fig. 2 and Fig. 3 with respect to predetermined direction B left, if deviation value is a negative value, then processor 10 determines that moving direction A depart from Fig. 2 and Fig. 3 with respect to predetermined direction B to the right.

Need to prove that the above-mentioned determination methods of processor 10 only is a kind of example, the utility model is not limited to this.For example, when the first and

second distance detector

2a and 2b are arranged on the mobile device 5, because alignment error, even longitudinal center's axis of mobile device 5 is parallel with reference component 1, also may there be difference in the first and

second distance detector

2a and 2b apart from the initial distance between the reference component 1.Yet, can be by returning to zero described difference as the benchmark null value.For the ordinary skill in the art, processor 10 can adopt any suitable method in this area based on the described deviation value of the first and second distance detecting calculated signals, judge whether depart B of moving direction A thus, and the drive signal that generation and described deviation value degree are answered, and then utilize described drive direction-control apparatus.For example, processor 10 can utilize the ratio of first and second distance L 1 and L2 to judge whether depart B of moving direction A.

Signal driver 11 is used for receiving drive signal and the drive current output drive signal to increase from processor 10.

As shown in figure 14, show the circuit diagram of signal driver.At processor 10 is under the situation of single-chip microcomputer, and the drive current as drive signal of single-chip microcomputer 10 outputs is generally smaller, for example less than 50mA, in order to drive bigger load, adopts signal driver 11 to increase from the drive current of single-chip microcomputer 10 outputs usually.For example, as shown in figure 14, behind the signal driver 11 of input signal by Darlington pipe array formation, drive current can increase to 500mA.

Signal driver 11 is sent to driving circuit 12 with the drive current that increases, and the driving direction control device 4 thus.

Below with reference to the direction correcting device of Fig. 4 description according to the utility model second embodiment.As shown in Figure 4, the direction correcting device that is used for mobile radiation checkout system according to the utility model second embodiment comprises the first distance detector 2a ' and second distance detecting device 2b ', first optoelectronic switch 45 and second optoelectronic switch 46, direction-control apparatus 4 (referring to Fig. 1), control module 3 (referring to Fig. 1), and the reference component (not shown) that is arranged on mobile device 5 the place aheads or rear.The first distance detector 2a ' and second distance detecting device 2b ' and first optoelectronic switch 45 and second optoelectronic switch 46 constitute direction detection device.Control module 3 comprises signal picker transmitter 43 and signal receiver 44, and other formations of control module 3 are identical with first embodiment, repeat no more here.

Signal picker transmitter 43 is used to gather the signal of the first distance detector 2a ' and second distance detecting device 2b ' and first optoelectronic switch 45 and second optoelectronic switch 46, and described signal wireless is sent to signal receiver 44.Then, signal receiver 4 for example sends to processor 10 by A/D converter 8 with the signal that receives, (it will be appreciated that so that judge whether the moving direction A of mobile device 5 and predetermined direction depart from and calculate deviation value, even without departing from, processor 10 also can calculate deviation value, and just departing from of this moment is to be zero).

First optoelectronic switch 45 and second optoelectronic switch 46 are used for sending for example conducting and/or cut-off signal to described control module 3, so that control module 3 is controlled at preset distance according to the signal that receives from first optoelectronic switch 45 and second optoelectronic switch 46 with described mobile device 5 and the described distance that is examined between the vehicle 6, thereby prevent mobile device 5 with respect to 6 translations to the left or to the right in Fig. 4 that are examined vehicle.In other words, control module 3 judges mobile device 5 according to the signal that receives from first optoelectronic switch 45 and second

optoelectronic switch

46 and 6 whether translation takes place with respect to being examined vehicle, so as not to carry out to be examined vehicle carry out scanning imagery check system portal 48 and be examined collision happens.

As shown in Figure 4, on the mobile device 5 block piece 47 can be set, when mobile device 5 with respect to being examined vehicle 6 translation does not take place, be that mobile device 5 and the distance that is examined between the vehicle 6 are preset distance, 45 conductings of first optoelectronic switch and second optoelectronic switch 46 part 47 that is blocked blocks (that is, second optoelectronic switch 46 disconnects).

Below the concise and to the point operation of describing according to the direction correcting device of the utility model second embodiment.

For example, will begin to move so that when being examined vehicle 6 and checking at mobile device 5, if mobile device 5 be examined distance between the vehicle 6 greater than preset distance, first and second

optoelectronic switches

45 and 46 all disconnect so at this moment.Control module 3 receives indication first and second

optoelectronic switches

45 and 46 signals that all disconnect, and determines mobile device 5 thus with respect to being examined vehicle 6 in Fig. 4 to left.Then, control module 3 produces the corresponding driving signal, driving direction control device 4, adjust the moving direction of mobile device 5 thus and then adjust mobile device 5 and be examined distance between the vehicle 6, when control module 3 receives indication first optoelectronic switch, 45 conductings and during signal that second optoelectronic switch 46 disconnects once more, driving direction control device 4 reset (that is mobile device 5 is moved along the direction straight line that is parallel to predetermined direction).

When control module 3 receives indication first and second

optoelectronic switches

45 and 46 all during the signal of conducting, then determine mobile device 5 and be examined distance between the vehicle 6 less than preset distance, at this moment, the operation that the moving direction of 4 pairs of mobile devices 5 of control module 3 direction of passage control device is adjusted is opposite with above-mentioned situation, repeats no more here.

Thus, according to second embodiment of the present utility model, by the first distance detector 2a ' and second distance detecting device 2b ' and first optoelectronic switch 45 and second optoelectronic switch 46 are set, not only the moving direction of mobile device 5 can be monitored in real time, and mobile device 5 can be controlled to the distance that is examined vehicle 6.

Need to prove, in direction correcting device, also the first distance detector 2a ' and second distance detecting device 2b ' can be set and first optoelectronic switch 45 and second optoelectronic switch 46 only are set according to the utility model second embodiment.In this case, the control module 3 only conducting by first optoelectronic switch 45 and second optoelectronic switch 46 and disconnection is determined mobile device 5 and whether the distance that is examined between the vehicle 6 is preset distance, when described distance departs from preset distance, control module 3 driving direction control device 4 are so that change the moving direction of mobile device 5, thereby described distance is adjusted into preset distance.

In addition, in the direction correcting device according to the utility model second embodiment, first optoelectronic switch 45 and second optoelectronic switch 46 are arranged on a side of mobile device 5 abreast.Yet for the ordinary skill in the art, first optoelectronic switch 45 and second optoelectronic switch 46 are provided with and are not limited to above-mentioned form, can be located at any suitable position.In addition, the quantity of optoelectronic switch is not limited to two, and any suitable quantity can be set.

First preferred embodiment of direction-control apparatus 4 is described below with reference to Fig. 5-8.As shown in Figure 5 and Figure 6, direction-control apparatus 4 comprises bearing circle 13 and the actuator 14 of the moving direction A that controls mobile device 5, for example, described bearing circle 13 can be the bearing circle of scanning car, actuator 14 is positioned at the rear side (for example be installed on the sidewall of pilothouse, the back will be described in detail) of pilot set S and extends to bearing circle 13 so that be connected with bearing circle 13 from the side of seat S.

Actuator 11 is connected separably with described bearing circle 13, thereby and is driven so that driving direction dish 13 rotates the moving direction A of control mobile devices 5 by the driving circuit 12 of control module 3.

And then direction-control apparatus 4 further comprises bindiny mechanism 18, and an end of described bindiny mechanism 18 links to each other with actuator 14, and the other end is connected separably with bearing circle 13.

More specifically, bindiny mechanism 18 comprises connecting link 19, installing plate 20, oscillating bearing 21 and pillar 22.

Installing plate 20 is for example fixing separably by the neighboring of bolt and bearing circle 13.As shown in Figure 7, pillar 22 is installed on the upper surface of installing plate 20, and an end of connecting link 19 links to each other with pillar 22 by oscillating bearing 21, so that can rotate with respect to pillar 22.Be provided with nut 23 on the top of pillar 22, nut 23 is positioned at connecting link 19 on the pillar 22.The other end of connecting link 19 is hinged and lock with nut 25 by bearing pin 24 and actuator 14.

Preferably, further comprise back up pad 27 according to the direction correcting device 100 of present embodiment, back up pad 27 for example is installed on the sidewall of scanning car rear cabin.Support 26 is installed on the back up pad 27, actuator 14 (for example, actuator 14 is the Worm and worm-wheel gearing of driven by motor, hydraulic cylinder, or cylinder, this will be discussed in more detail below) be installed on the support 26 by cross piece 28.Described cross piece 28 and support 26 are hinged so that form universal joint, thereby actuator 14 can rotate with respect to support 26.

More preferably, on described back up pad 27, Protection switch 29 is installed, and pressing plate 30 is installed in the rear end (left side among Fig. 5 and Fig. 6) of the universal joint that forms by cross piece 28 and support 26.When actuator 14 separates with bearing circle 13 and holds up, pressing plate 30 crash switches 29, thus make actuator 14 outage shut-down operations, as shown in Figure 8.Otherwise when actuator 14 falls down when engaging with bearing circle 13, pressing plate 30 crash switches 29, thereby the power supply of connecting actuator 14 are so that actuator 14 can move, as shown in Figure 5 and Figure 6.

Preferably, actuator 14 comprises the motor 15 that is driven by driving circuit 12, turbine 16 that links to each other with the output shaft of motor 15 and the worm screw 17 that engages with worm gear 16, worm screw 17 can rotatably and separably engage with bearing circle 13, also can connect by aforesaid bindiny mechanism 18.More specifically, worm screw 17 rotatably links to each other with an end of the connecting link 19 of bindiny mechanism 18, yet, in order to save cost, it is shorter that worm screw 17 can be made, and the telescopic tube (not shown) is set between worm screw 17 and connecting link 19, when worm screw 17 rotations, telescopic tube extends or shrinks, thereby moves 13 rotations of driving direction dish so that drive connecting link 19.

Driving circuit 12 is according to the drive motor 15 of processor 10, thereby worm gear 16 rotations drive worm screw 17 rotations and mobile, thereby worm drive connecting link 19 are moved steering wheel rotation 13, proofreaies and correct the moving direction A of mobile device 5 thus.

For those having ordinary skill in the art will appreciate that, the motor and the worm-and-wheel gear form that are not limited to describe in the foregoing description according to actuator 14 of the present utility model, alternatively, actuator 14 can adopt hydraulic cylinder, described hydraulic cylinder drive by control module and its lever and bindiny mechanism for example connecting link 19 link to each other, thereby according to 13 rotations of the deviation value driving direction dish between moving direction A and the predetermined direction B.And then above-mentioned hydraulic cylinder also can replace with cylinder.

The operation of the actuator of employing hydraulic cylinder and cylinder form and the class of operation of the actuator among above-mentioned first embodiment seemingly therefore for simple purpose, have been omitted their detailed description.

Second embodiment of direction-control apparatus 4 is described below in conjunction with accompanying drawing 9-12.As shown in Figures 9 and 10, Fig. 9 shows the structural representation according to the direction-control apparatus 4 of the utility model second embodiment, and Figure 10 is the vertical view of Fig. 9.Direction-control apparatus 4 according to the utility model second embodiment comprises bearing circle 13, gearing 31 and flexible traction piece 32.Gearing 31 is driven by control module 3 (driving circuit 12), and flexible traction piece 32 walks around bearing circle 13, and two ends connect respectively and are wound on the gearing 31 then.Preferably, described flexible traction piece 32 is a traction rope.

More specifically, gearing 31 comprises the motor 33 by driving circuit 12 drivings of control module 3, double output shaft speed reduction unit 34 by motor 33 drivings, be connected to first and second shaft coupling 35a and the 35b on two output shafts of double output shaft speed reduction unit 34, first and second

rolling wheel axle

36a and 36b that link to each other with the outgoing side of the first and

second shaft coupling

35a and 35b respectively, with first and second rolling wheel 37a and the 37b, the first and

second rolling wheel

37a and 37b are respectively installed on the first and second rolling wheel axle 36a and the 36b.

Need to prove that if the sense of rotation of two output shafts of double output shaft speed reduction unit 34 (i.e. the first and

second rolling wheel

37a and 37b) is identical, then the two ends of traction rope 32 are wrapped on the first and second rolling wheel 37a and the 37b around opposite direction respectively.Otherwise if the sense of rotation of two output shafts of double output shaft speed reduction unit 34 (i.e. first and second rolling wheel 37a and the 37b) is opposite, then the two ends of traction rope 32 are wrapped on the first and second rolling wheel 37a and the 37b around identical direction respectively.

More preferably, gearing 31 further comprises first and second supporting seat 38a and the 38b, the first and second supporting

seat

38a and 38b support first and second rolling wheel axle 36a and the 36b respectively, and the first and

second rolling wheel

37a and 37b lay respectively in the first and second supporting seat 38a and the 38b.The first and second overrunning clutch 39a and 39b are installed in respectively in the first and second shaft coupling 35a and the 35b, and are preferably internal tooth ratchet overrunning clutch.

Further, on the first and second supporting

seat

38a and 38b, be separately installed with first and second regulating device 40a and the 40b, be used to regulate the tensioning of traction rope 32.Preferably, the first and

second regulating device

40a and 40b are the form of adjuster bar, and first and second adjuster bar 40a and the 40b are passed at the two ends of flexible strand 32 respectively, are wound on the first and second rolling wheel 37a and the 37b around opposite direction then.

Preferably, be provided with on the excircle of bearing circle 13 by the U-shaped groove, traction rope 32 is bonded in the above-mentioned U-shaped groove, and fixing by clamp 41 and screw 42, prevents that traction rope 32 breaks away from the U-shaped grooves and skids in the U-shaped groove.Under off working state, for example, when needs with portable scanning system when a work place moves to another work place, traction rope 32 can be broken away from the U-shaped groove, drive by the driver.Gearing 31 preferably is arranged on the back (right side among Fig. 9) of the seat S in the pilothouse, therefore, with traction rope 32 with after bearing circle 13 separates, do not influence driver's driving.

When the moving direction A of mobile device 5 depart B, the driving circuit 12 of control module 3 sends drive signal to the motor 33 of drive unit 31, motor 33 drives 34 rotations of double output shaft speed reduction unit, thereby drive the first and

second rolling wheel

37a and 37b and rotate the amount corresponding with deviation value, traction rope 32 steering wheel rotations 13 thus are corrected to the moving direction A of mobile device 5 on the predetermined direction B.

Describe the method for utilizing the utility model direction correcting device that the deviation in driction of mobile radiation checkout system when carrying out the scanning radiation inspection proofreaied and correct below with reference to Figure 15, direction-control apparatus wherein is second embodiment of Fig. 9 to direction-control apparatus shown in Figure 12.Yet, be adapted to wherein to utilize the situation of first embodiment of direction-control apparatus equally for the description that persons of ordinary skill in the art may appreciate that down the faces direction correcting device.

Figure 15 is the schematic flow sheet according to the utility model direction correcting method.

As shown in figure 15, the first and

second distance detector

2a and 2b detection reference parts 1 are to first and second distance L 1 and the L2 of mobile device 5, and produce the first and second distance detecting signals, simultaneously the first and second distance detecting signals are sent to control module 3 (step S1).

The A/D converter 8 of control module 3 is digital signal (step S2) with the first and second distance detecting signal from analog conversion of signals, then first of digital signal form and the distance detecting signal by signal isolator 9 conversion by " electrical-optical-", then, the first and second distance detecting signals are sent to single-chip microcomputer 10 (step S3) from signal isolator 9.Single-chip microcomputer 10 utilizes whether depart B (step S4) of the first and second distance detecting signal determining moving direction A, for example by relatively the difference or the ratio of first and second distances judge whether moving direction A departs from and offset direction.For example, if L1, judges then that moving direction A departs from greater than L2 to the right in Fig. 1-3, single-chip microcomputer 10 calculates deviation value simultaneously, and the generation drive signal corresponding with this deviation value, here term " deviation value " comprises offset direction, for example, if deviation value is a negative value, then moving direction A departs from clockwise with respect to predetermined direction B, otherwise, if deviation value be on the occasion of, then moving direction A departs from counterclockwise with respect to predetermined direction B.For another example, if deviation value is greater than 1, then moving direction A departs from clockwise with respect to predetermined direction B, otherwise, if deviation value less than 1, then moving direction A departs from counterclockwise with respect to predetermined direction B.

The drive signal of single-chip microcomputer 10 then is sent to signal driver 11, and signal driver 11 will amplify and is sent to driving circuit 12 (step S5) from the drive signal of single-chip microcomputer 10.

Then, the motor 33 of driving circuit 12 driving direction control device 4 rotates, for example drive motor 33 rotates counterclockwise the angle corresponding with deviation value, motor 33 drives the first and

second rolling wheel

37a and 37b rotates, thereby traction rope 32 1 ends for example are wrapped on the first rolling wheel 37a, and the other end of traction rope 32 37b from second rolling wheel for example goes up unwinding, thereby driving direction dish 13 rotates an angle corresponding with deviation value, and the moving direction A of mobile device 5 is corrected on the predetermined direction B (step S6).

When moving direction A was consistent with predetermined direction B, flow process finished (step S7).Otherwise flow process turns back to step S1.

Equally, if first distance L 1 is less than second distance L2, moving direction A depart B left in Fig. 1 to 3 then is described, control module 3 drive motor 33 for example clockwise rotate, thereby drive traction rope 32 steering wheel rotations 13, this and the above-mentioned class of operation that departs to the right of correction seemingly are not described in detail here.

Need to prove that consistent with depart B if though moving direction A has been shown among Figure 15, then process finishes.Yet, to moving direction A whether the judgement of depart B can carry out in real time, that is to say that the first and

second distance detector

2a and 2b detect first and second distance L 1 and the L2 in real time.Alternatively, for example when the reference component 1 that adopts shown in Fig. 3, the first and

second distance detector

2a and 2b detect first and second distance L 1 and the L2 discontinuously, thereby periodically judge whether depart B of moving direction A.

Need to prove that if control module 3 (single-chip microcomputer 10) determines that according to the first and second distance detecting signals moving direction A does not have depart B, control module can not transmit drive signal to direction-control apparatus 4 so.In other words, also can be described as control module 3 is zero to the drive signal (drive current) of direction-control apparatus 4 transmission, and representative does not depart from.Therefore, for persons of ordinary skill in the art may appreciate that control module 3 is controlled direction-control apparatus 4 in real time and periodically so that proofread and correct moving direction A (when not departing from, the amount that needs to proofread and correct is zero).

In addition, for those having ordinary skill in the art will appreciate that, can be that the deviation value between moving direction A and the predetermined direction B sets predetermined threshold value, when having only absolute value when deviation value greater than predetermined threshold, control module 3 is just controlled the moving direction of direction-control apparatus 4 correction mobile devices 5.

Comprise above-mentioned direction correcting device according to the mobile radiation checkout system that proposes on the other hand of the present utility model.And other component part of mobile radiation checkout system, for example radiation source is arranged on the detector array on the extended and retractible arm, imaging system, similar in control system etc. and the prior art, above-mentioned component part can be integrated on the mobile device 5, thereby constitutes scanning car.For simple purpose, other formation and the operation thereof to mobile radiation checkout system here repeats no more.

Although illustrated and described embodiment of the present utility model, for the ordinary skill in the art, be appreciated that under the situation that does not break away from principle of the present utility model and spirit and can change that scope of the present utility model is limited by claims and equivalent thereof to these embodiment.

Claims

1. a direction correcting device that is used to have the mobile radiation checkout system of mobile device is characterized in that, comprising:

Direction detection device, described direction detection device detect the moving direction of described mobile device and produce the detection signal of the described moving direction of indication;

Direction-control apparatus, described direction-control apparatus is used to control the moving direction of described mobile device; With

Control module, described control module calculates deviation value between moving direction and the predetermined direction according to the detection signal that receives from described direction detection device, and according to described deviation value driving direction control device so that described moving direction is corrected on the predetermined direction.

2. direction correcting device according to claim 1, it is characterized in that, described direction detection device comprises first and second distance detectors, described first and second distance detectors produce the first and second distance detecting signals respectively, and wherein said control module is according to the described deviation value of the first and second distance detecting calculated signals.

3. direction correcting device according to claim 2 is characterized in that, described first and second distance detectors detect described mobile device to first and second distances that are examined target.

4. direction correcting device according to claim 3 is characterized in that, further comprises reference component, and wherein said first and second distance detectors detect first distance and the second distance of described mobile device to described reference component respectively.

5. direction correcting device according to claim 2 is characterized in that, described first and second distance detectors comprise laser range sensor.

6. direction correcting device according to claim 2 is characterized in that, described control module comprises:

Analog/digital converter, described analog/digital converter is a digital signal with the described first and second distance detecting signal from analog conversion of signals;

Processor, described processor goes out described deviation value so that produce the drive signal corresponding with deviation value according to the first and second distance detecting calculated signals that are converted to digital signal;

Signal driver, described signal driver reception also increases described drive signal; With

Driving circuit, described driving circuit are according to the drive direction-control apparatus of the increase that receives from signal driver, so that proofread and correct the moving direction of mobile device.

7. direction correcting device according to claim 6, it is characterized in that, described control module further comprises signal isolator, described signal isolator is connected between the input of the output of analog/digital converter and processor, is used to isolate the input signal that is input to it and from the output signal of its output.

8. direction correcting device according to claim 7 is characterized in that described signal isolator comprises photoisolator.

9. direction correcting device according to claim 8 is characterized in that described processor comprises single-chip microcomputer.

10. according to each described direction correcting device among the claim 1-9, it is characterized in that described direction-control apparatus comprises:

The bearing circle of the moving direction of control mobile device; With

Actuator, described actuator engage separably with described bearing circle and are driven by control module, thereby so that the driving direction dish rotates the moving direction of control mobile device.

11. direction correcting device according to claim 10 is characterized in that, described direction-control apparatus further comprises bindiny mechanism, and an end of described bindiny mechanism links to each other with actuator and the other end engages separably with the bearing circle of mobile device.

12. direction correcting device according to claim 11 is characterized in that, described bindiny mechanism comprises:

Connecting link, an end of described connecting link links to each other with actuator;

Pillar, the other end of described connecting link links to each other with described pillar by oscillating bearing, and is provided with the nut that is used for positioning link bar on the top of pillar;

Installing plate, described pillar is installed on the end face of installing plate, and the side of described installing plate joins on the neighboring of bearing circle separably so that the driving direction dish rotates.

13. direction correcting device according to claim 12, it is characterized in that, described direction-control apparatus further comprises support and cross piece, and wherein said cross piece and support are hinged so that form universal joint, and described actuator is installed on the support by the cross piece.

14. direction correcting device according to claim 13 is characterized in that, described direction-control apparatus further comprises:

Back up pad, described support are installed on the described back up pad;

Protection switch, described Protection switch are installed on the described back up pad; With

Pressing plate, described pressing plate are connected on the described universal joint, and when breaking away from bearing circle together with convenient actuator and bindiny mechanism, described pressing plate crash switch is so that make the actuator outage.

15. direction correcting device according to claim 10 is characterized in that, described actuator comprises:

Motor, described motor is driven by described control module;

Worm gear, described worm gear links to each other with the output shaft of described motor; With

Worm screw, described worm screw and the engagement of described worm gear, and the axial end of described worm screw is connected with described bindiny mechanism.

16. direction correcting device according to claim 10 is characterized in that, described actuator comprises hydraulic cylinder, and described hydraulic cylinder is driven by described control module and its cylinder bar links to each other with described bindiny mechanism.

17. direction correcting device according to claim 10 is characterized in that, described actuator comprises cylinder, and described cylinder is driven by described control module and its cylinder bar links to each other with described bindiny mechanism.

18., it is characterized in that described direction-control apparatus comprises according to each described direction correcting device among the claim 1-9:

Gearing, described gearing is driven by described control module; With

Flexible traction piece, the two ends of described flexible traction piece are walked around bearing circle and are connected respectively on the gearing.

19. the direction correcting device according to described in the claim 18 is characterized in that, described flexible traction piece is a traction rope.

20. the direction correcting device according to described in the claim 19 is characterized in that, described traction rope is bonded on separably by clamp and screw in the groove of excircle of bearing circle.

21. the direction correcting device according to described in the claim 20 is characterized in that, described gearing comprises:

Motor by the control module driving; With

By motor-driven double output shaft speed reduction unit, the two ends of described traction rope link to each other with two output shafts of double output shaft speed reduction unit respectively.

22. the direction correcting device according to described in the claim 21 is characterized in that, described gearing further comprises:

First and second shaft couplings, the input side of first and second shaft couplings link to each other with two output shafts of described speed reduction unit respectively;

The first and second rolling wheel axles, the described first and second rolling wheel axles link to each other with the outgoing side of first and second shaft couplings respectively and are supported by first and second supporting seats respectively; With

First and second rolling wheels, described first and second rolling wheels are respectively installed on the first and second rolling wheel axles, and the two ends of wherein said traction rope are wrapped in respectively on first and second rolling wheels.

23. the direction correcting device according to described in the claim 22 is characterized in that, described gearing further comprises first and second regulating devices, and described first and second regulating devices are used to regulate the rate of tension of described traction rope.

24. the direction correcting device according to described in the claim 23 is characterized in that, described gearing further comprises first and second overrunning clutches that are separately positioned in first and second shaft couplings.

25. the direction correcting device according to described in the claim 24 is characterized in that, described overrunning clutch comprises internal tooth ratchet overrunning clutch.

26., it is characterized in that described reference component comprises the flat part of the one that be arranged in parallel with described predetermined direction according to each described direction correcting device in the claim 4.

27. according to each described direction correcting device in the claim 4, it is characterized in that described reference component comprises a plurality of flat plate section, described a plurality of flat plate section are spaced apart from each other on described predetermined direction and arrange alignedly.

28. according to each described direction correcting device among the claim 1-9, it is characterized in that, described direction detection device comprises at least one optoelectronic switch, and wherein said control module is controlled at preset distance according to the signal that receives from described at least one optoelectronic switch with described mobile device and the described distance that is examined between the target.

29. direction correcting device according to claim 28 is characterized in that, optoelectronic switch is two.

30. direction correcting device according to claim 29 is characterized in that, described control module comprises:

The signal picker transmitter is used to gather the signal of described first and second distance detectors and described optoelectronic switch; With

Signal receiver is used for the described signal that wireless receiving sends from described data acquisition unit transmitter.

31. a mobile radiation checkout system is characterized in that, comprises according to each described direction correcting device among the claim 1-30.