JP2006077425A - System for monitoring inside of multistory parking space - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for monitoring the inside of a multistory parking space, which can surely detect the presence or absence of a person etc. in a vehicle. <P>SOLUTION: Elevator type parking equipment 1 is equipped with a pallet 8 operated to load and unload the vehicle 6, and an elevating platform 5 which is operated to lift/lower the pallet 8 along a shaft; and the vehicle 6 is loaded on the pallet 8 called to a loading/unloading story and stored. A microwave Doppler sensor MS for detecting the swing of part of the vehicle 8 or a vehicle body loaded on the called pallet 8 is provided inside the loading/unloading story. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a monitoring system for monitoring the inside of a multilevel parking lot at the entrance / exit floor, and in particular, a vehicle driver (and a passenger, a pet animal) entering the multilevel parking lot has left the inside of the entrance / exit floor of the parking lot. The present invention relates to an in-situ monitoring system for a multi-story parking lot that more reliably detects whether or not the vehicle is safe.

  In general, a multilevel parking garage equipped with a mechanical parking device is provided with an entry / exit floor (also referred to as an entry / exit section or an entry / exit room) defined at one or a plurality of locations. A driving operation panel is provided outside the venue. And, after the empty pallet (or cage or elevator with a comb fork or conveyor in a pallet-less type multi-story parking lot) is called to the entry / exit floor by the operation of this operation control panel, The entrance / exit door is opened, and the vehicle gets into the pallet by the driving of the vehicle driver and stops at the normal position.

  After that, the driver gets off and exits from the entrance / exit, and after the driver or the parking lot manager confirms the safety in the entrance / exit floor, the entrance / exit door is closed and a series of entrance / exit operations are performed. finish. Thereafter, the pallet on which the vehicle is mounted by driving a mechanical parking device is transported to a predetermined parking space or the like as necessary.

  In such a multistory parking lot, after entering the warehouse, the entrance / exit door is closed and the mechanical parking device is driven. It has become.

  That is, when leaving the vehicle, the person starts from a state outside the multilevel parking lot, and the vehicle leaves and completes from the inside of the entry / exit floor, so that there is almost no possibility that the person is trapped in the place.

  On the other hand, at the time of warehousing, the passenger is taken off the ground and urged to enter the vehicle, but if an infant or pet animal is on board, it must enter and enter the pallet. Then get off with the driver.

  Therefore, as a method of confirming the presence or absence of a person in such a place, a technique for detecting a person on the boarding / alighting deck part by image processing picked up by a photoelectric detector or an image pickup device, or a person in the vehicle by microwave Doppler Various techniques for detecting by a sensor have been proposed (see, for example, Patent Documents 1, 2, and 3).

JP-A-5-59839 JP 2002-167996 A Japanese Patent No. 3527362

  However, if an infant or pet animal is on board as described above, the driver may leave the vehicle after leaving the warehouse without being aware of the infant or pet animal sleeping in the back seat, etc. An unexpected situation is also expected.

  On the other hand, the microwave Doppler sensor disclosed in Patent Document 3 irradiates microwaves on the front windshield of the vehicle, obliquely downward from the front upper part inside the entry / exit floor, Since the structure is intended to detect the presence / absence of the vehicle, there is a drawback that a blind spot occurs in a rear seat or the like in the vehicle. In other words, when a smoking film (often mixed with metal components) is pasted on the side or rear window glass of the vehicle, it cannot be detected effectively even when irradiated with microwaves.

  Such a microwave Doppler sensor detects the presence or absence of a person by taking out a change component of a signal (0.2 to 0.5 Hz) due to a person's breathing, but a person in the front seat of the vehicle is surely Although it can be detected, there is a blind spot problem in which small infants and small animals in the back seat cannot be detected effectively because they are hidden behind the front seat. This is because if the seat frame is made of plastic, cloth, or skin, microwaves are transmitted but the metal frame portion is not transmitted.

  Also, in doors with glass windows, glass window parts transmit microwaves, but metal door bodies and trunks do not transmit microwaves, so the presence of people is detected behind these metal parts. It becomes a blind spot.

  In view of the above, the present invention has an object to provide an on-site monitoring system for a multi-story parking lot that can more reliably detect the presence or absence of a person in a vehicle.

  The technical means for solving the above-mentioned problems includes vehicle mounting means that is operated to get on and off the vehicle and that is transported along the transport path, and the vehicle is mounted on the vehicle mounting means that is called on the entry / exit floor. In the on-site monitoring system of the multistory parking lot that is stored, vehicle shake detection means for detecting a shake of a part of the vehicle or the vehicle body that is stored on the called vehicle mounting means is provided in the storage floor. In the point.

  In addition, during the vehicle shake monitoring time set in advance from the completion of the closing operation of the loading / unloading door to the start of the storage drive of the loaded vehicle after the loading of the vehicle with respect to the vehicle mounting means called on the loading / unloading floor, A structure may be employed in which the presence or absence of shaking of a part of the vehicle mounted on the vehicle mounting means or the vehicle body is monitored by the vehicle shake detection means.

  Furthermore, it is good also as a structure in which the storage drive of a vehicle is permission-controlled when the said vehicle shake detection means does not detect a part of said vehicle or the shake of a vehicle body during the said vehicle shake monitoring time.

  Moreover, it is good also as a structure provided with the alerting | reporting means for alerting | reporting when the said shaking is detected by the said vehicle shake detection means.

  According to the in-situ parking system monitoring system according to claim 1, the vehicle shake detection means for detecting a shake of a part of the vehicle or the vehicle body entered on the called vehicle mounting means in the entry / exit floor. If there are people or animals remaining in the vehicle, even if you are sleeping, even if you are sleeping, the seats and even the vehicle body will shake slightly, even if you are asleep. A vehicle that can detect a part of a vehicle or a shake of a vehicle body by means, and is easy to detect by a remarkable phenomenon associated with the remaining of a person, etc., compared to a conventional method of directly detecting a person or the like in a vehicle. Therefore, a blind spot can be effectively prevented from occurring, and the presence or absence of a person in the vehicle can be more reliably detected.

  According to the in-situ parking system monitoring system described in claim 2, storage of a vehicle that has been received after completion of the closing operation of the entry / exit door after the entry of the vehicle to the vehicle mounting means that has been called to the entry / exit floor. During the preset vehicle shake monitoring time until the start of driving, the vehicle shake detection means is configured to monitor the presence or absence of shaking of a part of the vehicle mounted on the vehicle mounting means or the vehicle body. If a part of the vehicle or the body shake is detected by the vehicle shake detection means during the monitoring time period, it is determined that a person or the like remains in the vehicle. Can be detected more reliably.

  Further, according to the in-situ parking system monitoring system according to claim 3, when the vehicle shake detection means does not detect a part of the vehicle or the shake of the vehicle body during the vehicle shake monitoring time, the storage drive of the vehicle is permitted. Since the control is such that the vehicle is stored when the presence of a person or the like is not detected in the vehicle, the storage in a state where the person or the like remains in the vehicle can be effectively prevented.

  Further, according to the in-situ parking system monitoring system according to claim 4, since the structure is provided with the notifying means for notifying when the shake is detected by the vehicle shake detecting means, the notifying means is provided. Thus, it is possible to effectively notify the situation in which a person or the like remains in the vehicle.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIGS. 1 to 3 show an elevator parking device 1 as an example of a mechanical parking device in a multilevel parking garage, and parking with an outer wall panel mounted thereon. Inside the tower 2, there is provided a parking structure 3 composed of a steel tower having a steel truss structure and a plurality of main shelf columns / sub-shelf columns supported and fixed to the steel tower.

  A central portion in the parking structure 3 is provided with a hoistway 4 extending in the vertical direction as a conveyance path, and an elevating platform 5 as a vehicle mounting means that can be moved up and down along the hoistway 4. Yes. In the left and right spaces along the hoistway 4, a plurality of stages of storage shelves 7 for storing vehicles for storing and storing the vehicles 6 are arranged in a hierarchy.

  Each of these parking shelves 7 is mounted with a pallet 8 for mounting on the vehicle, and each pallet 8 can be transferred between each parking shelf 7 and the lifting platform 5. The structure is stored in the parking shelf 7 while being placed on the pallet 8.

  The lifting platform 5 includes a lifting frame having a substantially rectangular frame structure, and four corner portions of the lifting frame are suspended by four wire ropes 9 as suspension ropes. Each of these four wire ropes 9 passes through each deflecting sheave 10 provided on the ceiling portion of the parking structure 3, and is then gathered at one place toward the driving vehicle 11 a of the elevating drive mechanism 11, and further drawn downward. Are connected to the counterweight 12.

  Then, by the forward / reverse drive of the lift drive mechanism 11, the drive wheel 11a is driven to rotate forward / reversely, each wire rope 9 is wound up and down, and the lift platform 5 is lifted / lowered. Here, a lifting / lowering device for moving up / down the lifting platform 5 by the wire rope 9, the deflecting sheave 10, the lifting / lowering drive mechanism 11, and the like is configured.

  Further, the lifting platform 5 is provided with a pallet transfer device for performing a transfer operation of the pallet 8 with each parking shelf 7.

  A pallet turning device for changing the direction of the vehicle 6 mounted on the pallet 8 on the floor surface of the pit 15 provided on the ground floor as an entry / exit floor on which the vehicle 6 gets on and off the pallet 8 14 is installed, and the elevator 5 arrives on the ground floor and is further lowered. As a result, the pallet 8 is delivered onto the swing frame 14a of the pallet swing device 14 and supported in a mounted manner. It is configured to change the direction of the vehicle 6 mounted on the pallet 8 by raising, turning, and lowering the frame 14a.

  2 to 4, the ground floor of the parking apparatus 1 is provided with a loading / unloading port 16 through which the vehicle 6 enters and leaves, and a loading / unloading port door 17 can be opened and closed freely at the loading / unloading port 16. Is provided. Furthermore, on the upper side of the frame structure 18 constituting the entrance / exit 16 and on the wall surface side in the parking structure 3 facing the entrance / exit 16, there are provided guide display plates 19, 20 by electric display, etc. The guidance display board 20 in the parking apparatus 1 is provided with a speaker for performing voice guidance and the like. In addition, a mirror 21 for checking the entry position for the driver is provided below the guidance display board 20.

  On both sides of the hoistway 4 on the ground floor, a boarding deck 22 is provided at a height that does not hinder the turning of the pallet 8 and constitutes a boarding board.

  Further, in the parking structure 3 on the ground floor, as shown in FIGS. 2 and 3, for example, a projector and a light receiver for detecting and controlling the entering / exiting state and stop position of the vehicle 6 with respect to the pallet 8 A plurality of photoelectric sensors PH <b> 1 to PH <b> 7 composed of pairs of are arranged at appropriate height positions.

  That is, in the vicinity of the entrance / exit 16, photoelectric sensors PH 1 and PH 2 that emit a horizontal beam in a direction substantially perpendicular to the entry direction of the vehicle 6 are disposed at an appropriate distance from the entry direction. ing. Further, a photoelectric sensor PH3 that emits a horizontal beam in a lateral direction inclined with respect to the approach direction is disposed in the central portion in the approach direction in the parking structure 3. Further, photoelectric sensors PH4 and PH5 that emit a horizontal beam in a direction substantially perpendicular to the approach direction are disposed at a distance and a distance from the approach direction in the parking structure 3 as appropriate. Are arranged.

  Further, photoelectric sensors PH6 and PH7 that emit beams in the approach direction of the vehicle 6 are disposed corresponding to both side portions of the pallet 8, respectively. At this time, each of the photoelectric sensors PH6 and PH7 has a structure in which, for example, a light projector on the back side is appropriately disposed at a height position, and a light receiver on the entrance / exit 16 side is disposed in an embedded state on the floor surface. It is set as the arrangement | positioning structure which radiate | emits a beam toward. On the light receiver side, a transparent lid is disposed on the floor surface, and the beam emitted from the projector is transmitted through the transparent lid and received by the light receiver.

  And it is controlled so that entering / exiting of the vehicle 6 is detected by shielding the beams of the photoelectric sensors PH1 and PH2, for example, if the photoelectric sensor PH1 is shielded from light after the photoelectric sensor PH1 is shielded. If it is determined that the vehicle 6 is received and the photoelectric sensor PH2 is shielded from light, and if the photoelectric sensor PH1 is also shielded in that state, it is determined that the vehicle 6 is leaving. The photoelectric sensor PH2 also has a structure that also functions as a detector for regulating the rear end position of the vehicle 6. If the vehicle 6 that enters the vehicle shields the beam of the photoelectric sensor PH2, the photoelectric sensor PH2 is controlled to promote forward movement. The

  The photoelectric sensor PH4 functions as a detector for restricting the stop position of the vehicle 6, and it is determined whether or not the vehicle 6 is mounted on the pallet 8 by light shielding of both the photoelectric sensor PH3 and the photoelectric sensor PH4.

  The photoelectric sensor PH5 functions as a detector for restricting the front end position of the vehicle 6, and is controlled so as to encourage backward movement when the entering vehicle 6 blocks the beam of the photoelectric sensor PH5. Moreover, if the beam is shielded by both the photoelectric sensor PH2 and the photoelectric sensor PH5, the vehicle is over-controlled and the vehicle is prompted to exit.

  Each photoelectric sensor PH6, PH7 functions as a left end and right end regulating detector for the vehicle 6, and is controlled so as to prompt the user to forget to close the door or to exit the vehicle when the vehicle width is exceeded by shielding the beam.

  In addition, in the state where the vehicle 6 is detected on the pallet 8 by the light shielding of both the photoelectric sensors PH3 and PH4, any one of the photoelectric sensors PH1, PH2, PH6, PH7, etc. is shielded. For example, it is controlled so as to determine that there is a person in the hall on the entry / exit floor. Here, these photoelectric sensors PH1, PH2, PH6, PH7, etc. have a structure that is also used as a human detection means for detecting the presence of people or animals in the place on the entry / exit floor.

  Furthermore, in the parking structure 3 on the ground floor, passive infrared sensors PS1 and PS2 for detecting people and animals entering the left and right boarding deck 22 areas are respectively arranged at appropriate height positions, and are guided. A microwave Doppler sensor MS for transmitting a microwave toward the vehicle 6 stored on the pallet 8 and detecting a person or an animal in the vehicle 6 is disposed at an upper position of the display board 20. In arranging the microwave Doppler sensor MS, it is preferable that the microwave Doppler sensor MS is attached to a place such as a foundation concrete floor where vibration and vibration are small in consideration of vibration of the wall of the parking tower 2 due to wind or the like.

  In addition, a driving operation panel 24 for controlling the operation of the parking apparatus 1 is provided at one side of the entrance / exit 16 outside the parking apparatus 1, and as shown in FIG. Includes a power switch 25 for turning on / off the power, a numeric keypad 26 for inputting various operation information such as a self ID number when used by a user, a speaker 27 serving also as voice guidance and an alarm, an emergency stop switch 28, A display unit 29 made of information display liquid crystal or the like is provided.

  Moreover, the control apparatus 30 as a control part which carries out driving control of the parking apparatus 1 is provided, and the control apparatus 30 is provided with CPU30a, memory 30b, etc., and raise / lower a raising / lowering platform according to the operation signal from the driving operation panel 24, etc. Control of raising / lowering of the elevator 5 by the device, transfer control of the pallet 8 by the pallet transfer device provided in the elevator 5, turning control of the pallet 8 by the pallet turning device 14, opening / closing control of the entrance door 17, each photoelectric Vehicle 6 and human detection control by receiving and blocking the beams of the sensors PH1 to PH7, detection control of humans and the like by passive infrared sensors PS1 and PS2, detection control of humans and the like in the vehicle by the microwave Doppler sensor MS, guidance display board Various display controls for 19 and 20 are performed, and alarm control for issuing an alarm from the speaker 27 as an alarm device in the event of an abnormality is performed.

  As shown in FIG. 6, the microwave Doppler sensor MS includes a local oscillator 32, a transmission antenna 33, a reception antenna 34, a mixer 35, and a signal output unit 36, and an output signal from the local oscillator 32 is connected to the transmission antenna 33. It is distributed to the mixer 35. Then, a predetermined microwave is transmitted as a transmission wave fs from the transmission antenna 33 toward the vehicle 6 as an object, and the reflected wave fb is received by the reception antenna 34. The received reception signal and the output signal are received. Are frequency-mixed by the mixer 35 and input to the CPU 30 a through the signal output unit 36.

  The control device 30 is controlled so as to determine the presence or absence of a moving object in the vehicle 6 from the input signal and perform a predetermined process in accordance with the determination of the presence or absence of the moving object.

  Next, control of the entering / exiting operation of the vehicle 6 in the parking apparatus 1 will be described based on the flowcharts shown in FIGS.

  First, it is determined whether a call operation for entering / exiting has been performed (step S1). If there is a call operation, it is determined whether the call operation is for entering (step S2). Called (step S3).

  Thereafter, it is determined whether or not the empty pallet 8 has arrived at the entry / exit floor (step S4). If the called empty pallet 8 arrives at the entry / exit floor, the entry / exit door 17 at the entry / exit entrance 16 is opened. Then (step S5), the driver drives the vehicle 6 and gets on the empty pallet 8 mounted on the lifting platform 5 (step S6).

  Thereafter, the process proceeds to step S7, where it is determined whether or not the vehicle 6 is stopped at the normal position based on the detection states of the photoelectric sensors PH1 to PH7 provided on the entry / exit floor, and the vehicle is not stopped at the normal position. The driver is informed to stop at the normal position by guidance display of normal position stop by the guidance display board 20 located in front of the hall and voice guidance by the speaker provided therein (step S8).

  If it is determined in step S7 that the vehicle 6 has stopped at the regular position, the guidance display board 20 or the like displays guidance for getting off the vehicle 6 and leaving the parking device 1 (step S9).

  A user such as a driver who gets off or leaves the vehicle then closes the entry / exit door 17 using the driving operation panel 24 (step S10). Then, it is determined whether or not the closing operation of the entry / exit door 17 is completed (step S11). If the closing operation is completed, a predetermined time T (for example, several seconds) as a vehicle shake monitoring time set in advance in the timer. Is started (step S12), and detection processing of moving objects such as people and animals in the vehicle 6 by the microwave Doppler sensor MS is started.

  That is, from the input signal from the signal output unit 36 in the microwave Doppler sensor MS, one N wavelength equivalent to fHz (f = 0.2 Hz to 0.5 Hz) corresponding to the frequency of human or animal respiration is cut out. (Step S13). Then, the degree of correlation of the waveforms of these N signals is calculated (step S14), and it is compared and determined whether or not the degree of correlation is equal to or greater than a predetermined specified value (step S15).

  At this time, if the respiratory signal is included in the input signal, a large degree of correlation is obtained, so it is determined that there is a person or animal, and the process proceeds to step S16, where “the person / animal remains in the vehicle”. "Get out of the car." Is displayed on the guidance display board 19 and the like, and the user is informed by a voice or an alarm from the speaker 27 as an alarm, and the entrance door 17 is opened. It is operated (step S17). And the time count by a timer is reset (step S18), and it returns to step S9. Here, in steps S13 to S16, processing for directly detecting a person or animal in the vehicle 6 is performed by the microwave Doppler sensor MS.

  In step S15, if the degree of correlation is small, a Doppler frequency Δf, which is the difference between the transmitted wave fs and the reflected wave fb, is obtained from the input signal from the microwave Doppler sensor MS (step S19). Then, a comparison is made to determine whether or not the Doppler frequency Δf is equal to or higher than a predetermined specified value (step S20).

  For example, as shown in FIG. 6, when an infant 38, an animal, or the like is in the rear seat 39, it is hidden by the vehicle body 40, and thus cannot be detected by the above-described direct detection method through the windshield 41 by the microwave Doppler sensor MS. . However, paying attention to the fact that infants 38 and animals can never remain at all even if considered in seconds, of course, if they move in a noise, even if they are asleep, they can breathe or roll over. As a result, the rear seat 39 is shaken, and the front seat 42 is also finely moved. Further, the entire vehicle body 40 is also slightly shaken through the suspension and the tire.

  Then, the transmission wave fs from the microwave Doppler sensor MS causes a Doppler shift in the reflected wave fb reflected by the vehicle body 40, the front seat 42, the rear seat 39, etc. where the vibration occurs, and the transmitted wave fs and the reflected wave fb. A difference greater than a predetermined specified value occurs. When the Doppler frequency Δf due to this difference is detected, it is determined that there is some moving object such as a person, animal, or other moving toy, and the process proceeds to step S21, where “human / animal or other moving object remains in the vehicle. "Please check." Is displayed on the guidance display board 19 etc., and the user is informed by voice or alarm from the speaker 27 as an alarm device, and the entrance / exit door 17 is opened (step S17). And the time count by a timer is reset (step S18), and it returns to step S9. Here, in steps S19 to S21, the microwave Doppler sensor MS indirectly detects a part of the vehicle 6 (the front seat 42, the rear seat 39, etc.) or a person or an animal in the vehicle 6 based on the shaking of the vehicle body. Detection processing is performed.

  In step S20, when the Doppler frequency Δf is small, it is determined whether or not a predetermined time T as a vehicle shake monitoring time set in the timer has elapsed (step S22), and the predetermined time T has not elapsed. Return to step S13.

  In step S22, if the predetermined time T has elapsed, it is determined whether only the photoelectric sensors PH3 and PH4 are in the light shielding detection state and the other photoelectric sensors PH1, PH2, PH5 to PH7 are in the light reception detection state (step S22). S23) If any of the other photoelectric sensors PH1, PH2, PH5 to PH7 besides the photoelectric sensors PH3 and PH4 is in the light-shielding detection state, it is determined that a person or animal is in the field, and the process proceeds to step S24. , “There is a possibility that people / animals may remain in the hall. Please confirm.” The guidance display board 19 and the like are used for guidance display, as well as voice or warning from the speaker 27 as an alarm device. The user is notified and the entry / exit door 17 is opened (step S17). And the time count by a timer is reset (step S18), and it returns to step S9.

  In step S23, if only the photoelectric sensors PH3 and PH4 are in the light-shielding detection state and the other photoelectric sensors PH1, PH2, and PH5 to PH7 are in the light-detection state, then the passive infrared sensors PS1 and PS2 are used for humans and animals. Is detected, and if it is in the detection state, the process proceeds to step S24. If it is in the non-detection state, it is determined that no person or the like remains in the field, and the elevator drive mechanism 11 and the like are moved up and down. A drive permission command is output to the platform lifting / lowering device (step S26), the time counting by the timer is reset (step S27), the lifting platform 5 on which the vehicle 6 is mounted rises, and the pallet 8 in the storage state is replaced with the original parking shelf 7 (Step S28), and a series of work is completed.

  In step S2, if the call operation is not a warehousing but a warehousing, the process proceeds to step S30, where the pallet 8 requested for warehousing is called to the warehousing / exiting floor, and the called pallet 8 has arrived at the warehousing / leaving floor Is determined (step S31).

  When the pallet 8 arrives at the entry / exit floor, the pallet 8 is turned 180 degrees by driving the pallet turning device 14 to change the direction of the mounted vehicle 6, and the direction of the vehicle 6 is the direction of the entry / exit 16. (Step S32).

  When the direction change by the pallet turning device 14 is completed, the entry / exit door 17 is opened (step S33), the user enters the parking device 1 and gets into the vehicle 6 and exits by forward driving (step S33). S34).

  Thereafter, the process proceeds to step S35, where it is determined whether or not all the photoelectric sensors PH1 to PH7 are in the received light detection state, and if any one of the photoelectric sensors PH1 to PH7 detects the light shielding state, it is determined that the vehicle is in the middle of leaving. . When the vehicle 6 leaves the field, all the photoelectric sensors PH1 to PH7 enter a non-detection state in which the light shielding state is not detected, and the user then performs the closing operation of the entrance door 17 with the driving operation panel 24. For example (step S36), the entrance / exit door 17 is closed.

  Then, the lifting / lowering platform 5 is on standby at the loading / unloading floor with the empty pallet 8 mounted thereon, and a series of work is completed (step S37).

  The present embodiment is configured as described above. In addition to direct detection of people and animals through the windshield 41 by the microwave Doppler sensor MS, humans, animals and other moving toys remain in the vehicle 6. Then, even if it is asleep, even if it is asleep, the seats 39 and 42 and the vehicle body 40 are slightly shaken by breathing or turning over. Indirect detection of people, animals, etc. in the vehicle 6 is also performed based on the shaking of the vehicle or the vehicle body, so that it is possible to effectively prevent the occurrence of blind spots as in the prior art, and the existence of people, etc. in the vehicle 6 is more reliably determined. Can be detected more effectively, and the confinement of people in the venue can be prevented more effectively. In this case, coupled with the detection function of people and animals outside the vehicle 6 in the field by the photoelectric sensors PH1 to PH7 and the passive infrared sensors PS1 and PS2, there is an advantage that the confinement of the person in the field can be more reliably prevented.

  In addition, as a vehicle shake monitoring time set in advance from the completion of the closing operation of the loading / unloading door 17 to the start of the storage drive of the loaded vehicle 6 after the loading of the vehicle 6 to the lifting platform 5 called on the loading / unloading floor. During the predetermined time T, the microwave Doppler sensor MS is configured to monitor the presence or absence of shaking of a part of the vehicle 6 mounted on the lifting platform 5 or the vehicle body. If it is detected that a person or the like remains in the vehicle 6, there is an advantage that the presence or absence of the person or the like in the vehicle 6 can be more reliably detected by continuing monitoring for a predetermined time T. And after the entrance door 17 is closed, the entrance / exit floor is wrapped in a quiet state in which no mechanical parts are driven, and even if the parking tower 2 is exposed to wind and rain, the outer wall panel only vibrates somewhat. Thus, the warehousing vehicle 6 located at the center of the warehousing floor and isolated from the outer wall portion is not moved finely. Accordingly, if even a part of the vehicle 6 is shaken during this vehicle shake monitoring time period, it is considered that some moving object (human / animal, other moving toys, etc.) remains in the vehicle 6, which is more reliable. Detection accuracy is obtained.

  Furthermore, since the predetermined time T as the vehicle shake monitoring time, when the shake of a part of the vehicle 6 or the vehicle body is not detected by the microwave Doppler sensor MS, the storage drive of the vehicle 6 is permitted to be controlled. Since the control is such that the vehicle 6 is stored when the presence of a person or the like is not detected in the vehicle 6, the storage in the state where the person or the like remains in the vehicle 6 can be effectively prevented.

  Further, when the microwave Doppler sensor MS detects a shake of a part of the vehicle 6 or the vehicle body, the structure is such that it is notified by the guidance display plates 19 and 20 and the speaker (alarm device) 27 as notification means. Thus, it is possible to effectively notify the situation in which a person or the like remains in the vehicle 6.

  FIG. 11 shows the second embodiment, and the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  That is, in the first embodiment, the microwave Doppler sensor MS as the vehicle shake detection means is arranged at the upper position of the guide display board 20 located in front of the vehicle 6 in the intrusion direction. In the embodiment, a microwave is transmitted toward the vehicle body 40 (for example, a metal part of the door) of the vehicle 6 stored on the pallet 8 to detect the shaking of the vehicle body 40, which is indicated by a virtual line in FIG. Thus, it is set as the structure which has arrange | positioned the microwave Doppler sensor MS to the height suitably in the side position in the parking structure 3. In the arrangement of the microwave Doppler sensor MS, it is preferable that the microwave Doppler sensor MS is attached to a place such as a foundation concrete floor where vibration and vibration are small in consideration of the vibration of the wall of the parking tower 2 due to wind or the like. Other structures are the same as those in the first embodiment.

  Therefore, the control of the entering / exiting operation of the vehicle 6 in the present embodiment is substantially the same as in the first embodiment.

  That is, if the vehicle 6 is stored, as shown in FIG. 7, the process is the same from step S1 to step S12. After step S12, the process proceeds to step S41 shown in FIG. From the input signal from the Doppler sensor MS, the Doppler frequency Δf, which is the difference between the transmitted wave fs and the reflected wave fb, is obtained. Then, a comparison is made to determine whether or not the Doppler frequency Δf is equal to or higher than a predetermined predetermined value (step S42).

  Then, if a Doppler frequency Δf greater than the specified value is detected, it is determined that there are people, animals, etc., and the process proceeds to step S43, where “person / animal or other moving objects may remain in the car. "Please confirm." Is displayed on the guidance display board 19 and the like, and the user is informed by voice, alarm, etc. from the speaker 27 as an alarm device, and the entrance door 17 is opened. (Step S44). And the time count by a timer is reset (step S45), and it returns to step S9.

  In step S42, if the Doppler frequency Δf is small, the process proceeds to step S22 shown in FIG. 9 to determine whether or not the predetermined time T as the vehicle shake monitoring time set in the timer has elapsed as described above. If it is determined that the predetermined time T has not elapsed, the process returns to step S13.

  In step S22, if the predetermined time T has elapsed, it is determined whether only the photoelectric sensors PH3 and PH4 are in the light shielding detection state and the other photoelectric sensors PH1, PH2, PH5 to PH7 are in the light reception detection state (step S22). S23) If any of the other photoelectric sensors PH1, PH2, PH5 to PH7 besides the photoelectric sensors PH3 and PH4 is in the light-shielding detection state, it is determined that a person or animal is in the field, and the process proceeds to step S24. , “There is a possibility that people / animals may remain in the hall. Please confirm.” The guidance display board 19 and the like are used for guidance display, as well as voice or warning from the speaker 27 as an alarm device. The user is informed and the entry / exit door 17 is opened (step S44). And the time count by a timer is reset (step S45), and it returns to step S9.

  In step S23, if only the photoelectric sensors PH3 and PH4 are in the light-shielding detection state and the other photoelectric sensors PH1, PH2, and PH5 to PH7 are in the light-detection state, then the passive infrared sensors PS1 and PS2 are used for humans and animals. Is detected, and if it is in the detection state, the process proceeds to step S24. If it is in the non-detection state, it is determined that no person or the like remains in the field, and the elevator drive mechanism 11 and the like are moved up and down. A drive permission command is output to the platform lifting / lowering device (step S26), the time counting by the timer is reset (step S27), the lifting platform 5 on which the vehicle 6 is mounted rises, and the pallet 8 in the storage state is replaced with the original parking shelf 7 (Step S28), and a series of work is completed.

  On the other hand, in the case of leaving the vehicle 6, the control is performed in the same manner as in the first embodiment.

  Therefore, the present embodiment has the same effect as the first embodiment.

  Further, in the present embodiment, if the microwave Doppler sensor MS is configured to be used as an actual vehicle detection sensor for detecting whether the vehicle 6 is mounted on the pallet 8, the actual vehicle detection in the first embodiment is performed. The photoelectric sensor PH3 can be omitted, and the cost can be reduced.

  As the microwave Doppler sensor MS in each of the above embodiments, a known microwave Doppler sensor MS as disclosed in Japanese Patent Application Laid-Open No. 2004-85396, Japanese Patent Publication No. 6-93569, or the like is used as appropriate. Good. In addition, the detection method using the microwave Doppler sensor MS is the same as the detection method disclosed in Japanese Patent Application Laid-Open No. 2001-283347 and the like for detecting a part of the vehicle 6 or the vehicle body 40. What is necessary is just to apply suitably.

  Further, when detecting the shaking of the vehicle 6, not only the vehicle body 40 and the door portion but also a tire or the like may be used.

  FIGS. 13 to 15 show a third embodiment, and the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  In the first embodiment, the structure using the microwave Doppler sensor MS as the vehicle shake detection means is shown. However, in this embodiment, the vibration sensor is adopted as the vehicle shake detection means, and the vehicle 6 is a pallet. For example, a load cell 45 is used as a vibration sensor in the pallet turning device 14 as a boarding table that supports the pallet 8 when the pallet 8 is stored.

  That is, on the upper surface of the turning frame 14a in the pallet turning device 14, a pallet support portion 14b for supporting the pallet 8 in a mounting manner at four positions is provided, and vibration isolation is provided at two positions on the diagonal position. The load cell 45 is incorporated in each of the contact plate 46 made of a material. Other structures are the same as those in the first embodiment.

  Therefore, the control of the entering / exiting operation of the vehicle 6 in the present embodiment is substantially the same as in the first embodiment.

  In other words, if the vehicle 6 is stored, the process is the same from step S1 to step S12 as shown in FIG. 7, and after step S12, the process proceeds to step S51 shown in FIG. Load W1a acting on 45 and load W1b acting on the other second load cell 45 are taken in, respectively.

  Thereafter, after a predetermined minute time (for example, several seconds), the load W1a of the first load cell 45 and the load W1b of the second load cell 45 are taken in again (step S52), and respective load differences ΔW1 and ΔW2 are obtained (step S53). It is determined whether or not each load difference ΔW1, ΔW2 is within a predetermined value (step S54). That is, when a person or the like remains in the vehicle 6, the weight detected by each load cell 45 varies due to the shaking of the vehicle body 40 even if the total weight detected by the plurality of load cells 45 does not change when the person or the like moves. By doing.

  If any one of the load differences ΔW1 and ΔW2 exceeds a predetermined value, it is determined that a person, an animal, or the like exists in the vehicle 6, and the process proceeds to step S55. Is displayed on the information display board 19 or the like, and is also notified to the user by voice or alarm from the speaker 27 as an alarm device. The mouth door 17 is opened (step S56). And the time count by a timer is reset (step S57), and it returns to step S9.

  In step S52, if both of the load differences ΔW1 and ΔW2 are within a predetermined value, it is determined whether or not the number of sampling times of the load differences ΔW1 and ΔW2 has reached a predetermined number (step S58). If not, the process returns to step S51. When the number of sampling times reaches the predetermined number, the process proceeds to step S22 shown in FIG. 9 to determine whether or not the predetermined time T as the vehicle shake monitoring time set in the timer has elapsed. If not, the process returns to step S51.

  In step S22, if the predetermined time T has elapsed, it is determined whether only the photoelectric sensors PH3 and PH4 are in the light shielding detection state and the other photoelectric sensors PH1, PH2, PH5 to PH7 are in the light reception detection state (step S22). S23) If any of the other photoelectric sensors PH1, PH2, PH5 to PH7 besides the photoelectric sensors PH3 and PH4 is in the light-shielding detection state, it is determined that a person or animal is in the field, and the process proceeds to step S24. , “There is a possibility that people / animals may remain in the hall. Please confirm.” The guidance display board 19 and the like are used for guidance display, as well as voice or warning from the speaker 27 as an alarm device. The user is notified and the entry / exit door 17 is opened (step S56). And the time count by a timer is reset (step S57), and it returns to step S9.

  In step S23, if only the photoelectric sensors PH3 and PH4 are in the light-shielding detection state and the other photoelectric sensors PH1, PH2, and PH5 to PH7 are in the light-detection state, then the passive infrared sensors PS1 and PS2 are used for humans and animals. Is detected, and if it is in the detection state, the process proceeds to step S24. If it is in the non-detection state, it is determined that no person or the like remains in the field, and the elevator drive mechanism 11 and the like are moved up and down. A drive permission command is output to the platform lifting / lowering device (step S26), the time counting by the timer is reset (step S27), the lifting platform 5 on which the vehicle 6 is mounted rises, and the pallet 8 in the storage state is replaced with the original parking shelf 7 (Step S28), and a series of work is completed.

  On the other hand, in the case of leaving the vehicle 6, the control is performed in the same manner as in the first embodiment.

  Therefore, the present embodiment has the same effect as the first embodiment.

  In addition, in this embodiment, although the structure which has arrange | positioned the load cell 45 in two places of the diagonal position in the four pallet support parts 14b is shown, it is the same also as a structure which has arrange | positioned the load cell 45 in four places, respectively. Applicable to.

  Moreover, although the structure which has arrange | positioned the load cell 45 to the turning frame 14a side of the pallet turning apparatus 14 is shown, the structure arrange | positioned on the road surface on which the wheel in the pallet 8 rides, or the lower surface side of the pallet 8 may be sufficient.

  Furthermore, although the structure using the load cell 45 for the vibration detection of the vehicle 6 is shown, other vibration sensors that can detect the vibration of the vehicle 6 may be used.

  In each of the above embodiments, the structure using the microwave Doppler sensor MS or the load cell 45 is shown as the vehicle shake detection means. However, the shake of the vehicle 6 or the like is performed by image processing of images sequentially captured by a television camera or the like. In other words, the present invention is not limited to the above-described embodiments, and a known structure that can detect the shaking of the vehicle 6 or the like may be adopted as appropriate.

  Furthermore, although the parking apparatus 1 having a structure in which the entry / exit floor is a ground floor is shown, a structure in which two floors other than the ground floor are entry / exit floors may be used, and there are a plurality of entry / exit floors. The structure provided in the location may be sufficient and it is not restricted to the said embodiment at all.

  Moreover, in each embodiment, although the elevator type parking apparatus 1 by the pallet 8 system is shown, it can be applied to other parking apparatus structures such as a vertical circulation system and an underground pallet circulation system. The vehicle 6 is directly mounted on the conveyor mounted on the lifting platform 5 without using the vehicle, the vehicle 6 tires are mounted on the comb forks formed on the lifting platform 5, A so-called pallet-less parking device that does not use a pallet 8 such as a method of sandwiching each tire of the vehicle 6 with a pair of front and rear slide forks that are formed may be used. There may be.

  For example, in an underground parking apparatus, the load cell 45 may be incorporated with a configuration similar to that of Japanese Utility Model Publication No. 63-48766.

  Furthermore, although the structure which has arrange | positioned photoelectric sensor PH1-PH7 and passive infrared sensor PS1 and PS2 as a means to detect the person and animal outside the vehicle 6 in the field is shown, it is imaged by the microwave Doppler sensor MS or imaging device. A structure that detects the presence or absence of a person by image processing, a structure that detects the presence or absence of a person by detecting a person's speaking or walking sound by a sound detector such as a sound collecting microphone, or a pressure of walking on the floor surface A structure in which a treading pressure detector such as a so-called mat-shaped pressure sensitive switch is arranged and a structure for detecting the presence or absence of a person by detecting the walking pressure may be appropriately adopted.

It is the external appearance front view which removed a part of exterior board of the elevator type parking device concerning a 1st embodiment of the present invention. It is the II-II sectional view taken on the line of FIG. It is the III-III sectional view taken on the line of FIG. It is a front view of the entrance / exit part. It is a control block diagram. It is detection operation explanatory drawing of a microwave Doppler sensor. It is a flowchart of an entering / exiting operation | movement. It is a flowchart of an entering / exiting operation | movement. It is a flowchart of an entering / exiting operation | movement. It is a flowchart of an entering / exiting operation | movement. It is principal part explanatory drawing which shows 2nd Embodiment. It is a flowchart of an entering / exiting operation | movement. It is principal part explanatory drawing which shows 3rd Embodiment. It is the same top view. FIG. 4 is an enlarged view of part A of FIG. 3. It is a flowchart of an entering / exiting operation | movement.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Elevator type parking apparatus 4 Hoistway 5 Lift platform 6 Vehicle 7 Parking shelf 8 Pallet 14 Pallet turning device 16 Entrance / exit port 17 Entrance / exit door 19 Guide display board 20 Guide display board 27 Speaker (alarm)
39 Rear seat 40 Car body 42 Front seat 45 Load cell PH1 to PH7 Photoelectric sensor PS1, PS2 Passive infrared sensor MS Microwave Doppler sensor

Claims (4)

In the on-site monitoring system for a multi-story parking lot that includes vehicle mounting means that is operated to get on and off the vehicle and that is transported along the transport path, and that stores and mounts the vehicle on the vehicle mounting means that is called on the entry / exit floor.
An on-site monitoring system for a three-dimensional parking garage, characterized in that a vehicle shake detection means for detecting a shake of a part of a vehicle or a vehicle body received on the called vehicle mounting means is provided in the loading / unloading floor. . In the on-site monitoring system of the multilevel parking garage according to claim 1,
The vehicle shake during a preset vehicle shake monitoring time from the completion of the closing operation of the loading / unloading door to the start of the storage drive of the loaded vehicle after the vehicle is loaded on the vehicle loading means called on the loading / unloading floor. An on-site monitoring system for a three-dimensional parking lot, wherein the presence or absence of shaking of a part of a vehicle or a vehicle body mounted on the vehicle mounting means is monitored by a detection means. In the on-site monitoring system of the multilevel parking garage according to claim 2,
An in-situ parking system monitoring system for a multi-story parking lot, wherein when the vehicle shake detection means does not detect a shake of a part of the vehicle or a vehicle body during the vehicle shake monitoring time, permission to store the vehicle is controlled. In the on-site monitoring system of the multistory parking lot in any one of Claims 1 thru | or 3,
An on-site monitoring system for a multi-story parking garage, comprising a notification means for notifying when the vehicle shake detection means detects the shake.

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