JP6629370B2 - Elevator contactless power supply system - Google Patents

Description

  An embodiment of the present invention relates to a contactless power supply system for an elevator that supplies electric power required for operation of each device in a contactless manner.

  In recent years, interest in non-contact power supply technology has increased, and the technology has been used in various fields. The non-contact power supply technology mainly uses the principle of electromagnetic induction, and transmits power in a non-contact manner by applying an AC magnetic flux generated in a primary coil to a secondary coil to generate an electromotive force. Technology.

  In non-contact power supply systems used in elevators, cordless tail cords that supply power consumed in the car in a non-contact manner, and in elevators without machine rooms, main circuit control devices such as motors and inverters are installed in the hoistway. By using non-contact power supply, it has been considered to omit wiring work at the time of installation.

  In non-contact power supply to a car, a power supply device is provided on the hoistway side and a power receiving device is provided on the car side, and when the car comes to the power supply floor (floor where the power supply device is installed), the power supply device Power is supplied to the power receiving device in a non-contact manner. The car is provided with a battery for storing contactlessly supplied power. The devices (lighting devices, doors, etc.) in the car are driven using the electric power stored in the battery. In addition, by supplying power to the main circuit control device in a non-contact manner, it is possible to eliminate a power cable through which a high voltage and a large current flows, thereby ensuring safety of maintenance work.

JP 2012-175857 A JP 2016-145088 A

  In the above-mentioned non-contact power supply system for an elevator, a battery for storing electric power supplied in a non-contact manner is provided for each device. When a power outage occurs, the operation of the elevator is continued using the electric power stored in these batteries. The operation at this time is referred to as “continuous operation at power failure”.

  The time of the continuous operation at the time of power failure is determined by the remaining amount of each battery. However, if there is a bias in the remaining battery power of each device, even if the remaining battery power of a certain device is sufficient, the operation is continued according to the device with a low remaining battery power, so the operation time may be shortened. is there.

  The problem to be solved by the present invention is to provide a non-contact power supply system for an elevator that can continue operating as long as possible by efficiently using the power of a battery provided in each device when a power failure occurs. It is to be.

  A non-contact power supply system for an elevator according to one embodiment supplies power to at least a plurality of devices including a hoist and a car in a non-contact manner.

The non-contact power supply system of the elevator is provided in each of the devices and stores a plurality of batteries that store power supplied to the devices, and mutually supplies power of the batteries between the devices. A power supply mechanism, remaining amount detecting means for detecting the remaining amount of each of the batteries, and power supply controlling means for controlling the amount of power supply to each of the batteries according to the remaining amount of each of the batteries detected by the remaining amount detecting means; Wherein the power supply control means supplies power from the battery of the other device to the battery of the device via the power supply mechanism when the remaining battery power of some of the devices falls below a certain value. to is intended, the hoisting machine is installed in the machine room or elevator shaft, to the battery of the hoisting machine, regardless of the position of the cab, power feeding of a non-contact from the power supply controller , When a power failure occurs, characterized in that the electric power is fed in a non-contact from the battery of another device.

FIG. 1 is a diagram illustrating a configuration of an elevator according to the first embodiment. FIG. 2 is a diagram showing a configuration inside an elevator car according to the embodiment. FIG. 3 is a block diagram showing a functional configuration of the elevator control device according to the embodiment. FIG. 4 is a flowchart illustrating the operation of the non-contact power supply system according to the embodiment when the car is powered. FIG. 5 is a flowchart illustrating a power supply control process of the contactless power supply system according to the embodiment. FIG. 6 is a diagram for explaining a power supply control method for each battery in the embodiment. FIG. 7 is a flowchart illustrating a power supply control process of the contactless power supply system according to the second embodiment. FIG. 8 is a diagram showing non-contact power supply from the battery of the car to the battery of the hoist in the same embodiment. FIG. 9 is a diagram showing non-contact power supply from the battery of the hoist to the battery of the car in the embodiment. 10 is a block diagram showing a functional configuration of the elevator control device according to the third embodiment. FIG. 11 is a flowchart illustrating a power supply control process of the contactless power supply system according to the embodiment. FIG. 12 is a block diagram showing the functional configuration of the elevator control device and the configuration of the in-car devices in the fourth embodiment. FIG. 13 is a flowchart illustrating a power supply control process of the contactless power supply system according to the embodiment.

  Hereinafter, embodiments will be described with reference to the drawings.

(1st Embodiment)
FIG. 1 is a diagram illustrating a configuration of an elevator according to the first embodiment. In addition, in the example of FIG. 1, the configuration of the 1: 1 roping type elevator is shown, but the invention is not particularly limited to this configuration.

  A car 11 and a counterweight 12 are provided in a hoistway 10 of an elevator. The car 11 and the counterweight 12 are respectively supported by guide rails (not shown) so as to be able to move up and down. The car 11 is connected to one end of the main rope 13, and the counterweight 12 is connected to the other end of the main rope 13. The main rope 13 is wound around a main sheave 15 attached to a rotating shaft of a hoisting machine 14. The hoisting machine 14 is installed in, for example, a machine room of a building. In a machine roomless type elevator without a machine room, a hoisting machine 14 and an elevator control device 16 are installed in the hoistway 10.

  The elevator control device 16 controls the entire elevator including drive control of the hoisting machine 14, and is sometimes called a “control panel”. In the example of FIG. 1, a configuration in which the elevator control device 16 is installed in the car 11 is shown. However, the configuration is not particularly limited to this, and the elevator control device 16 is installed in the machine room of the building together with the hoisting machine 14. It may be.

  When the hoisting machine 14 is driven by a driving instruction from the elevator control device 16, the car 11 and the counterweight 12 move up and down in a slippery manner via the main rope 13 as the main sheave 15 rotates.

  The car 11 is provided with a car control device 17. The car control device 17 controls various devices installed in the car 11 and the like. As shown in FIG. 2, a car door 18 is installed in the front of the car 11 and opens and closes by driving a door opening / closing device (motor) 19. A car operation panel 21 having various operation buttons including a display 20 and a destination floor button is installed near the car door 18. Further, a lighting device 22, an air conditioner 23, and the like are installed on the ceiling surface. These in-car devices are driven by electric power of a battery 30b described later.

  Here, in the present embodiment, power is supplied to each device including the car 11 and the hoist 14 in a non-contact manner. Specifically, power is supplied to the hoist 14 in a non-contact manner between the power supply device 31a installed at the top of the hoistway 10 and the power receiving device 32a installed below the hoist 14. Done. The power supply device 31a is connected to the power supply control device 33. The power supply device 31a and the power receiving device 32a are in an opposed state. Thereby, required power is supplied from the power supply device 31a to the power reception device 32a in a non-contact manner. A battery 30a having a predetermined capacity is installed in the hoisting machine 14, and the power received by the power receiving device 32a is stored in the battery 30a. The electric power stored in the battery 30a is used for driving the motor of the hoisting machine 14, the inverter, and the like.

  Power is supplied to the car 11 in a non-contact manner between a power feeding device 31b installed on a specific floor (power feeding floor) in the hoistway 10 and a power receiving device 32b installed on the car 11. Is The power supply device 31b is connected to the power supply control device 33. Thus, when the car 11 stops at a specific floor (power supply floor), required power is supplied from the power supply device 31b to the power reception device 32b in a non-contact manner. A battery 30b having a predetermined capacity is installed in the car 11 and power received by the power receiving device 32b is stored in the battery 30b. The electric power stored in the battery 30b is used for driving the above-described in-car devices, and also for driving the elevator control device 16 installed in the car 11 and the like.

  The power supply device 31b is installed, for example, on the top floor. In addition, the power supply device 31b may be installed on a reference floor where the car 11 stops most frequently, or the power supply device 31b may be installed on a plurality of places such as a top floor, a middle floor, and a bottom floor. It is good to put it. The power receiving device 32b is installed on a side surface of the car 11 so as to face the power feeding device 31b when the car 11 comes to the power supply floor.

  Further, in this system, in order to exchange electric power between the hoisting machine 14 and the car 11 in a non-contact manner, a power supply device 31c and a power receiving device 32d are installed below the hoisting machine 14, and , A power receiving device 32c and a power feeding device 31d are installed. The power feeding device 31c and the power receiving device 32c are used when the hoisting machine 14 supplies power to the car 11 in a non-contact manner. The power feeding device 31d and the power receiving device 32d are used when power is supplied from the car 11 to the hoist 14 in a non-contact manner.

  As described above, the electric power required for driving each device is provided in a non-contact manner, thereby eliminating the need for a power cable connected to each device. Note that signal transmission between the distributed control devices may be wired or wireless.

  In the example of FIG. 1, the car 11 and the hoisting machine 14 are the devices to be contactlessly supplied with power, and the batteries 30b and 30a provided for the respective devices are configured to store the power required for each device. A configuration may be adopted in which power is supplied to a large number of devices in a non-contact manner and power is stored in batteries provided in these devices. For example, when the elevator control device 16 is installed at an arbitrary location in the hoistway 10 instead of the car 11, the elevator control device 16 supplies power to the elevator control device 16 in a non-contact manner and is provided in the elevator control device 16. A configuration in which electric power is stored in a battery may be adopted.

  The batteries of the respective devices are provided in respective battery units (not shown), and the battery units incorporate a remaining amount detection circuit, a charge / discharge circuit, and the like.

  FIG. 3 is a block diagram illustrating a functional configuration of the elevator control device 16.

  The elevator control device 16 is provided with a remaining amount detection unit 16a, a power supply control unit 16b, and a power consumption learning unit 16c as functional configurations related to the present embodiment.

  The remaining amount detection unit 16a detects the remaining battery amount of each device including the car 11 and the hoisting machine 14. For example, the remaining amount of the battery 30a provided in the hoisting machine 14 is detected by acquiring a remaining amount state detection signal wirelessly or by wire from a remaining amount detection circuit of a battery unit (not shown) corresponding to the battery 30a. Do. The detection of the remaining amount of the battery 30b provided in the car 11 is performed by acquiring a remaining amount state detection signal wirelessly or by wire from a remaining amount detection circuit of a battery unit (not shown) corresponding to the battery 30b.

  The power supply control unit 16b controls the power supply amount according to the remaining battery power of each device detected by the remaining power detection unit 16a. The power consumption learning unit 16c learns the power consumption of each device based on the traveling pattern of the car 11. The power supply control unit 16b controls the amount of power supplied to the battery of each device in consideration of the power consumption of each device learned by the power consumption learning unit 16c.

  Next, the operation of the present system will be described.

  In the following description, for example, when saying “below a certain value”, “the certain value” may or may not be included. When "constant value" is included when it is "less than or equal to a certain value", "constant value" is not included when "more than a certain value" is mentioned. The same applies to the case of “above the reference value / below the reference value”.

  FIG. 4 is a flowchart showing the operation of the present system when feeding a car.

  During normal operation, the car 11 moves on each floor in response to a hall call or a car call. The “hall call” is a signal of a call registered by operating a hall call button (not shown) installed at the hall on each floor, and includes information on the registered floor and the destination direction. The "car call" is a call signal registered by operating a destination call button (not shown) provided in the car room, and includes information on the destination floor.

  Here, the power supply operation to the car 11 is performed when the remaining amount of the battery 30b provided in the car 11 decreases to a certain value or less (for example, 50% or less of the total capacity) (Yes in step S11). A charge request signal is output to the elevator control device 16 from a corresponding battery unit (not shown).

  Upon receiving the charge request signal, the elevator control device 16 first checks the current call registration status. When the hall call and the car call are not registered, that is, when the car 11 is in a non-directional standby state (Yes in step S12), the elevator control device 16 controls the car 11 Move to the power supply floor (step S13).

  As shown in FIG. 1, a power supply device 31b is installed on the power supply floor, and when the car 11 arrives at the power supply floor, the power receiving device 32b provided on the car 11 and the power supply device 31b face each other. Then, non-contact power supply is performed (step S14). The electric power supplied to the car 11 by this non-contact power supply is converted into direct current by an AC / DC converter (not shown), and then stored in the battery 30b.

  After the charging of the battery 30b is completed, when a new call (a hall call / a car call) is registered (Yes in step S15), the elevator control device 16 causes the car 11 to respond to the registered floor of the call (step S16). ).

  When a call is registered in the middle of charging, if a required minimum remaining amount (for example, 10% of the total capacity) is satisfied, charging may be interrupted to answer the call, or a predetermined amount ( For example, charging may be performed until the capacity reaches 80% of the total capacity, and then the call may be answered.

  Further, the power supply is performed when the remaining amount of the battery 30b is equal to or less than a certain value. good.

  When the car 11 stops on the power supply floor due to the call registration, non-contact power supply is performed each time. The power supply floor (the floor on which the power supply device 31b is installed) is not limited to one location, and may be a plurality of locations.

  When the remaining amount of the battery 30a provided in the hoisting machine 14 decreases to a certain value or less (for example, 50% or less of the total capacity), the elevator control device 16 drives the power supply device 31a wirelessly or by wire. The power is supplied from the power supply device 31a to the battery 30a through the power receiving device 32a. In this case, unlike the car 11, since the positional relationship between the power supply device 31a and the power receiving device 32a is fixed, when the remaining capacity of the battery 30a is sufficient (for example, 80% or more of the total capacity), power is supplied to the battery 30a. Instead, power may be directly supplied to the hoisting machine 14.

  Here, in the present embodiment, when performing non-contact power supply to each device, the power supply operation is controlled according to the remaining battery power of these devices. The situation at this time is shown in FIG.

  FIG. 5 is a flowchart showing the power supply control processing of the present system.

  During normal operation, the elevator control device 16 detects the remaining battery power of each device including the car 11 and the hoist 14 (step S21). If the remaining battery level of each device has fallen below the reference value set for each device (Yes in step S22), the elevator control device 16 supplies a predetermined amount of power to the battery of each device at a predetermined timing. The power supply device is controlled (step S23). For example, when the remaining battery capacity of the car 11 falls below the reference value, the car 11 is moved to the power supply floor when there is no call registration, and then the power supply device 31b is driven to supply a fixed amount of power. To charge the battery 30b. The “reference value” may be the same value as the fixed value (for example, 50% of the total capacity) shown in step S11, or may be a different value.

  On the other hand, when the remaining battery power of each device is equal to or greater than the reference value (No in step S22), the elevator control device 16 supplies power to each device based on the priority (step S24). At this time, the elevator control device 16 controls the power supply amount according to the remaining battery power of each device in preparation for the continuous operation at the time of power failure (step S25).

  That is, normally, the priority of the main equipment such as the hoisting machine 14 is set higher. For this reason, for example, when a power failure occurs after the charging of the hoisting machine 14, although the battery power of the hoisting machine 14 is sufficiently remaining, the remaining battery level of the car 11 runs out first, and Operation may not be continued. Therefore, it is necessary to always charge the battery of each device in consideration of prolonged continuous operation at the time of power failure.

  Therefore, the elevator control device 16 controls the amount of power supply according to the remaining battery power of each device, and optimizes the remaining battery power among the devices. More specifically, the power supply control method described below is used to optimize the remaining battery power among the devices.

  (1) The battery level of each device including the car 11 and the hoisting machine 14 is averaged so that the remaining battery amount and the ratio are the same. For example, it is assumed that there are three batteries A, B, and C having the same capacity, and the remaining capacity is as shown in FIG. In such a case, the power supply amount is controlled so that the remaining amounts of the batteries A, B, and C are averaged as shown in FIG.

  (2) The battery of a device having high power consumption such as the hoisting machine 14 is supplied with more power than the batteries of other devices in consideration of the power consumption.

  (3) The quick power supply is performed with priority given to the battery of the device whose remaining battery power is less than or equal to a certain ratio.

  (4) The power consumption of each device is learned from the operation pattern of the car 11 during normal operation (for example, at what rate the power of each device is consumed), and the power consumption for each battery is determined based on the learning result. Control the amount of power supply. For example, a device that consumes more power depending on the operation pattern of the car 11 is supplied with more power than other devices.

  As described above, according to the first embodiment, the power supply amount to the battery of each device is controlled and charged in consideration of the prolongation of the continuous operation at the time of a power failure, so that when the power failure occurs, It is possible to avoid a situation in which the operation is stopped due to a shortage of the remaining battery of the unit, and it is possible to use the power of each battery efficiently and continue the operation as long as possible.

(Second embodiment)
Next, a second embodiment will be described.

  In the second embodiment, when the remaining battery power of some devices decreases, power is supplied from the battery of another device to the battery of the device.

  Since the system configuration is the same as that in FIG. 1, a process in the case where non-contact power supply is performed between the car 11 and the hoisting machine 14 will be described here with reference to the flowchart in FIG. 7.

  FIG. 7 is a flowchart illustrating a power supply control process of the contactless power supply system according to the second embodiment.

  When a power failure occurs during the normal operation, the operation is switched to the power failure continuous operation, and the operation of the car 11 is continued using the power stored in the battery of each device (step S31). At that time, the elevator control device 16 first checks the remaining amount of the battery 30a provided in the hoisting machine 14, which is a main device (step S32).

  When the remaining battery level of the hoisting machine 14 has decreased to a certain value or less (for example, 50% or less of the total capacity) (Yes in step S33), the elevator control device 16 is provided in the car 11. The remaining capacity of the battery 30b is checked (step S34). If the remaining battery capacity of the car 11 is equal to or more than a certain value and does not hinder the operation (Yes in step S35), the elevator control device 16 moves the car 11 to a position near the hoisting machine 14 (step S36). ), Power is supplied from the battery 30b of the car 11 to the battery 30a of the hoist 14 (step S37).

  Specifically, for example, when the hoisting machine 14 is installed in a machine room of a building, the car 11 is moved to the top floor, and the power feeding device 31 d installed on the car 11 and the bottom of the hoisting machine 14 The installed power receiving device 32d is opposed to the installed power receiving device 32d. In this state, the power of the battery 30b is transmitted from the power feeding device 31d to the power receiving device 32d in a non-contact manner through a charging / discharging circuit in a battery unit (not shown) on the car 11 side, and the power is transmitted to the hoisting machine 14 side. The battery 30a is charged via a charging / discharging circuit in a battery unit (not shown). It is assumed that the operation control of each circuit related to power supply including the above-mentioned charge / discharge circuit is performed by the elevator control device 16 wirelessly or by wire.

  The situation at this time is shown in FIG.

  When the remaining battery level of the hoisting machine 14 is low, contactless power is supplied from the battery 30b of the car 11 to the battery 30a of the hoisting machine 14 in accordance with the remaining battery level of the car 11. In this case, the power supply from the battery 30b of the car 11 to the battery 30a of the hoisting machine 14 may be a fixed amount, or the power may be supplied such that the remaining amount and the ratio are averaged.

  In step S35, when the remaining battery capacity of the car 11 is equal to or smaller than the predetermined value (No in step S35), the battery power is not transferred between the two, and the continuous operation at the time of the power failure is executed.

  On the other hand, if the remaining battery level of the hoisting machine 14 is equal to or less than the predetermined value in step S33 (No in step S33), the elevator control device 16 checks the remaining level of the battery 30b provided in the car 11. (Step S38).

  When the remaining battery level of the car 11 has fallen below the certain value (Yes in step S39), the elevator control device 16 checks the remaining level of the battery 30a provided in the hoisting machine 14 (step S39). S40). If the remaining battery level of the hoisting machine 14 is equal to or more than a certain value and does not hinder operation (Yes in step S41), the elevator control device 16 moves the car 11 to a position near the hoisting machine 14 (step S41). S42), power is supplied from the battery 30 of the hoisting machine 14 to the battery 30b of the car 11 (step S43).

  Specifically, when the hoisting machine 14 is installed in the machine room of the building, the car 11 is moved to the top floor, and the power supply device 31c installed at the bottom of the hoisting machine 14 and installed on the car 11 With the received power receiving device 32c. In this state, the power of the battery 30a is transmitted from the power supply device 31c to the power receiving device 32c in a non-contact manner via a charging / discharging circuit in a battery unit (not shown) on the hoisting machine 14 side, and the power is transmitted to the car 11 side. The battery 30b is charged via a charging / discharging circuit in a battery unit (not shown). It is assumed that the operation control of each circuit related to power supply including the above-mentioned charge / discharge circuit is performed by the elevator control device 16 wirelessly or by wire.

  FIG. 9 shows this state.

  When the remaining battery level of the car 11 is low, wireless power is supplied from the battery 30 a of the hoisting machine 14 to the battery 30 b of the car 11 in accordance with the remaining battery level of the hoisting machine 14. In this case, the power supply from the battery 30a of the hoisting machine 14 to the battery 30b of the car 11 may be a fixed amount, or the power may be supplied so that the remaining amount and the ratio are averaged.

  In step S39 or S41, when the remaining battery level of the hoisting machine 14 is equal to or less than the predetermined value, the battery power is not transferred between the two, and the continuous operation at the time of power failure is executed using the current remaining battery level.

  As described above, according to the second embodiment, when the power failure occurs, if the remaining battery level of one of the car 11 and the hoisting machine 14 is reduced to a certain value or less, the other battery remaining Delivery of electric power is performed according to the amount. As a result, it is possible to eliminate the bias of the remaining battery level between the car 11 and the hoisting machine 14 and to continue the continuous operation during a power failure as long as possible.

  In the above-described second embodiment, the description has been given by taking the two devices of the car 11 and the hoisting machine 14 as an example. However, a configuration in which battery power is transferred between different devices may be adopted. A configuration in which battery power is transferred between devices may be adopted.

(Third embodiment)
Next, a third embodiment will be described.

  Normally, when the car 11 moves downward in the hoistway 10, if the load of the car 11 at that time is heavier than the counterweight 12, no power is required, and the hoist 14 functions as a generator. That is, power is generated. Similarly, when the car 11 moves in the upward direction, if the load on the car 11 at that time is lighter than the counterweight 12, no power is required, and the hoisting machine 14 functions as a generator to generate electric power. Occurs. The operation of the car 11 without the need for power is called "regenerative operation", and the electric power generated at that time is called "regenerative electric power". On the other hand, an operation that requires the power of the hoisting machine 14 is called “powering operation”.

  Even during continuous operation during a power outage, regenerative power is generated, for example, when driving downward with a large number of users from the top floor or when driving with a small number of users from the bottom floor. This regenerative electric power is stored in a battery 30a provided in the hoisting machine 14. Therefore, in the third embodiment, when regenerative power is expected, the power charged in the battery 30a is controlled so as to be preferentially consumed by being transferred to another device, and the regenerative power generated later is used to control the battery. By replenishing the remaining amount of the battery 30a, the continuous operation at the time of a power failure can be lengthened.

  The system configuration is the same as in FIG. However, as shown in FIG. 10, the elevator control device 16 includes a power prediction unit 16d as a function related to the third embodiment.

  The power prediction unit 16d predicts the generation of regenerative power based on the operation pattern of the car 11. Specifically, for example, it is predicted that regenerative electric power will be generated when a large number of users are carried from the upper floor to the lower floor in the daytime or the like and operated. The amount of power at this time is determined by the position of the car 11, the load, and the like. Therefore, for example, a regenerative power table T1 storing the relationship between the operation pattern and the regenerative power for each predetermined time is prepared, and the regenerative power table T1 is predicted with reference to the regenerative power table T1 including the power amount obtained during the regenerative operation.

  The power supply control unit 16b controls the power of the battery 30a in accordance with the remaining amount of the battery installed in a specific device to which the regenerative power predicted by the power prediction unit 16d is provided in each device during the continuous operation during a power failure. To other devices. The “specific device” refers to the hoisting machine 14, and the power supply control unit 16 b supplies the power of the battery 30 a installed in the hoisting machine 14 to the battery of each device including the car 11.

  FIG. 11 is a flowchart illustrating a power supply control process of the contactless power supply system according to the third embodiment.

  When a power failure occurs during normal operation, the operation is switched to the power failure continuous operation, and the operation of the car 11 is continued using the electric power stored in the battery of each device (step S41). At this time, when the generation of regenerative power is predicted by the power prediction unit 16d (Yes in step S42), the elevator control device 16 assumes that the power is stored in the battery 30a provided in the hoisting machine 14. Then, the following processing is performed.

  That is, the elevator control device 16 checks the remaining amount of the battery 30a provided in the hoist 14 (step S43). As a result, when the remaining amount of the battery 30a is equal to or more than the predetermined value (Yes in step S44), the elevator control device 16 supplies power from the battery 30a to the batteries of the respective devices including the car 11 (step S45).

In this case, the battery with the lowest remaining amount among the batteries of each device is given priority, and power is supplied from the battery 30a of the hoisting machine 14 according to a fixed amount or the amount of power expected from the regenerative power. In the case of the car 11, power can be supplied only on the power supply floor during normal operation, and there are many devices in the car. Therefore, priority may be given to power supply to the battery 30 b of the car 11. When the regenerative electric power is generated, it is stored in the battery 30a of the hoisting machine 14. Thereby, the remaining amount of the battery 30a is replenished.

  As described above, according to the third embodiment, when regenerative power is expected, power is supplied from the hoisting machine 14 to which the regenerative power is supplied to other devices, thereby prolonging the continuous operation during a power failure. Can be achieved.

  In the third embodiment, the description has been given assuming that the regenerative power is stored in the battery 30a of the hoist 14. However, a specific device that stores the regenerative power is determined among the devices, and the specific device is stored in the battery 30a. Power may be supplied from the battery to the battery of another device.

(Fourth embodiment)
Next, a fourth embodiment will be described.

  The car 11 is provided with various devices such as a door opening / closing device 19, a display 20, a car operation panel 21, a lighting device 22, and an air conditioner 23 shown in FIG. I do. Here, if the remaining battery level of the car 11 is low, even if power is received from the battery 30a of the hoisting machine 14 in anticipation of regenerative power during continuous operation during a power outage, sufficient power is supplied to the devices in the car. The situation that cannot be turned on occurs. Therefore, in the fourth embodiment, the power consumption is suppressed by restricting the operation of some or all of the devices in the car according to the remaining battery level of the car 11.

  FIG. 12 is a block diagram illustrating a functional configuration of the elevator control device 16 according to the fourth embodiment.

  The elevator control device 16 includes a device control unit 16e as a function related to the fourth embodiment. The device control unit 16e limits the operation of some or all of the devices provided in the car 11 when the remaining battery capacity of the car 11 is equal to or less than a certain value. Each device provided in the car 11 includes a door opening / closing device 19, a display 20, a car operation panel 21, a lighting device 22, an air conditioner 23, and the like shown in FIG.

  In the system configuration illustrated in FIG. 1, the elevator control device 16 is provided in the car 11. However, since the elevator control device 16 is a main control circuit, the elevator control device 16 is excluded from an operation restriction target.

  FIG. 13 is a flowchart illustrating a power supply control process of the contactless power supply system according to the fourth embodiment. Note that in FIG. 13, the processing in steps S51 to S55 is the same as the processing in steps S41 to S45 in FIG.

  That is, when a power failure occurs during the normal operation, the operation is switched to the continuous operation during the power failure, and the operation of the car 11 is continued using the electric power stored in the battery of each device (step S51). At this time, if the generation of the regenerative power is predicted by the power prediction unit 16d, the elevator control device 16 rides from the battery 30a provided that the remaining amount of the battery 30a provided in the hoisting machine 14 is equal to or more than a certain value. Power is supplied to the battery of each device including the car 11 (steps S51 to S55).

  Here, the elevator control device 16 checks the remaining amount of the battery 30b provided in the car 11 (step S56). As a result, when the remaining amount of the battery 30b is equal to or less than the predetermined value (Yes in step S57), the elevator control device 16 restricts a part or all of the operations of the in-car devices by the device control unit 16e. (Step S58).

  Here, "restricting a part or all of the operation of the equipment in the car" specifically means each of the door opening / closing equipment 19, the display 20, the car operation panel 21, the lighting equipment 22, the air conditioning equipment 23, and so on. Is to limit at least one of the devices, or to limit the operation of all the devices.

  The method of restricting the operation differs depending on the device. For example, in the case of the door opening / closing device 19, the rotation speed of the door motor is set lower than usual to drive. In the case of the display device 20, the brightness of the screen is made lower than usual. In the case of the car operation panel 21, the brightness at the time of turning on the button is set lower than usual. In the case of the lighting device 22, the brightness of the lighting is set lower than usual. In the case of the air conditioner 23, the wind power is reduced as compared with the normal time. The point is that the operation may be limited so as to suppress power consumption.

  Alternatively, the number of devices to be restricted may be increased stepwise according to the remaining amount of the battery 30b of the car 11. In this case, as the remaining amount of the battery 30b is smaller, the number of devices to be restricted is increased. The order in which the number of restricted devices is increased is determined in advance in accordance with the degree of importance or the like.

  Further, the operation restriction may be strengthened stepwise according to the remaining amount of the battery 30b. For example, in the case of the lighting device 22, the brightness of the lighting is reduced as the remaining amount of the battery 30b is smaller. Further, both the stepwise increase of devices to be restricted and the stepwise strengthening of the operation restriction may be performed in accordance with the remaining amount of the battery 30b.

  As described above, according to the fourth embodiment, when the car 11 is being supplied with power from the battery 30a of the hoisting machine 14, some or all of the devices in the car according to the remaining battery level of the car 11 , The amount of power consumed by the operation of the devices in the car can be suppressed, and the operation of the elevator can be continued for a long time during a power outage.

  In the fourth embodiment, the function (device control unit 16e in FIG. 12) of restricting the operation of the in-car device is provided in the elevator control device 16, but the function is provided in the car control device 17 so that the The control device 17 may be configured to execute the processing of step S58.

  According to at least one embodiment described above, in the event of a power failure, a non-contact power supply system for an elevator that can continue operating as long as possible by efficiently using the power of a battery provided in each device. Can be provided.

  Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These new embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and their equivalents.

  DESCRIPTION OF SYMBOLS 10 ... hoistway, 11 ... car, 12 ... counterweight, 13 ... main rope, 14 ... hoisting machine, 15 ... main sheave, 16 ... elevator control device, 16a ... remaining amount detection part, 16b ... power supply control part, 16c: power consumption learning unit, power prediction unit, 16d: power prediction unit, 16e: device control unit, 18: car door, 19: door opening / closing device, 21: car operation panel, 22: lighting device, 23: air conditioning device, 30a, 30b: battery, 31a to 31d: power supply device, 32a to 32d: power reception device, 33: power supply control device.

Claims (12)

In a non-contact power supply system of an elevator that supplies power to at least a plurality of devices including a hoist and a car in a non-contact manner,
A plurality of batteries that are provided in each of the devices and store power supplied to the devices,
A power supply mechanism for mutually supplying power of the batteries between the devices;
Remaining amount detecting means for detecting the remaining amount of each battery;
Power supply control means for controlling the amount of power supply to each battery according to the remaining amount of each battery detected by the remaining amount detection means,
The power supply control means includes:
When the remaining battery level of some of the devices falls below a certain value, power is supplied from the battery of the other device to the battery of the device via the power supply mechanism ,
The hoist is installed in a machine room or a hoistway,
Regardless of the position of the car, the battery of the hoist is wirelessly supplied with power from the power supply control device. contactless power supply system of the elevator, characterized in that it is. The power supply control means includes:
The non-contact power supply system for an elevator according to claim 1, wherein the power supply amount is controlled so that the remaining amounts of the respective batteries are averaged. The power supply control means includes:
The non-contact power supply system for an elevator according to claim 1, wherein more power is supplied to a battery provided in a device having high power consumption among the batteries than to batteries of other devices. The power supply control means includes:
2. The non-contact power supply system for an elevator according to claim 1, wherein the quick power supply is performed with priority given to the battery with the least remaining amount among the batteries. Power consumption learning means for learning the power consumption of each device based on the operation pattern of the car,
The power supply control means includes:
2. The non-contact power supply system for an elevator according to claim 1, wherein a power supply amount to each battery is controlled in consideration of power consumption of each device learned by the power consumption learning means. The power supply control means includes:
When the remaining battery capacity of the car falls below a certain value, the car is moved to the vicinity of the hoist, and the battery of the hoist is fed from the battery of the hoist to the battery of the car, and When the remaining battery capacity of the upper machine falls below a certain value, the car is moved to a position near the hoist, and power is supplied from the battery of the car to the battery of the hoist. The non-contact power supply system for an elevator according to claim 1. Power prediction means for predicting the generation of regenerative power based on the operation pattern of the car,
The power supply control means includes:
The power supply of the battery is supplied to another device according to the remaining battery level of a specific device to which the regenerative power predicted by the power prediction means is provided among the respective devices. Contactless power supply system for elevators. The specific device includes the hoist,
The power supply control means includes:
The non-contact power supply system for an elevator according to claim 7, wherein when regenerative power is stored in a battery installed in the hoist, the battery supplies the battery of the car in a non-contact manner.   When the car is receiving power from a battery installed in the hoist, some or all of the devices provided in the car when the remaining battery capacity of the car is equal to or less than a certain value. The non-contact power supply system for an elevator according to claim 8, further comprising device control means for restricting the operation of the elevator. The device control means includes:
The elevator according to claim 9, wherein the number of devices to be restricted among the devices provided in the car is increased stepwise according to the remaining battery power installed in the specific device. Contact power supply system. The device control means includes:
10. The non-contact power supply system for an elevator according to claim 9, wherein an operation restriction on each of the devices provided in the car is strengthened stepwise according to a remaining amount of the battery installed in the specific device. The device control means includes:
In accordance with the remaining amount of battery installed in the specific device, the number of devices to be restricted among the devices provided in the car is increased stepwise and the operation restriction on the device is strengthened stepwise. The non-contact power supply system for an elevator according to claim 9, wherein:

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