The present invention relates to a transportation system, an elevator system, and a method as defined in the claims.
The instantaneous electric power flowing in a power supply system varies. For instance, the power taken from the electric network of a building and likewise the power possibly returned into the electric network varies with time. However, an electricity supply connection is usually designed according to the highest power requirement, and therefore the variation in power also affects the costs of power supply to the building. Many other components in different power supply systems are also designed according to the highest power to be handled.
For example, in an elevator system power is supplied from an electricity network to the elevator motor in order to move the elevator car. The supply of power to the motor is generally implemented using a frequency converter. When the elevator car is braked by the motor, power is also returned from the motor to the frequency converter, from which it is often transferred further back into the electricity network. The instantaneous power supplied to the motor or returning from the motor is generally greater during acceleration and braking of an elevator system than during constant-speed operation.
Publication U.S. Pat. No. 4,545,464 proposes an elevator system in which braking power returning from the motor is fed into the electricity supply of the elevator system.
To solve the problems referred to above as well as those discussed in the below description of the invention, a novel method for handling temporally varying power in a power supply system is disclosed as an invention.
Embodiments of the invention are defined by what is disclosed in the claims. Inventive embodiments are also presented in the description part of the present application. The inventive content disclosed in the application can also be defined in other ways than is done in the claims below. The inventive content may also consist of several separate inventions, especially if the invention is considered in the light of explicit or implicit sub-tasks or with respect to advantages or sets of advantages achieved. In this case, some of the attributes contained in the claims below may be superfluous from the point of view of separate inventive concepts.
In the invention, “electric quantity constituting a load on a component” refers e.g. to a voltage across the poles of the component, to a current flowing through the component, and also to the frequency and/or rate of change of the current and/or voltage. The electric quantity can be defined repeatedly e.g. by determining the instantaneous value of the quantity, by calculating the mean value or root-mean-square value of the quantity between the instants of determination, or by interpolating the value of the electric quantity.
“Power supply circuit” in the invention refers to a circuit consisting of electric devices, components and wirings through which electricity is supplied to the system.
The advantages achieved by the invention include at least one of the following:
The arrangement of the invention comprises determination of an electric quantity constituting a load on a component, which electric quantity constituting a load on the component is determined repeatedly while the component is exposed to the load, said arrangement comprising estimation of instantaneous load capacity of the component, which estimation of instantaneous load capacity is performed using a limitation criterion set for the load capacity of the component.
This limitation criterion indicates the longest possible operating time of the component under a given loading condition. For the limitation criterion, a representation with respect to the electric quantity constituting a load on the component is prepared, and a limitation criterion corresponding to the defined electric quantity constituting a load on the component is derived repeatedly from the said diagram while the component is exposed to the load. The estimate of instantaneous load capacity of the component is determined on the basis of both the limitation criterion defined substantially at the instant of estimation and the limitation criteria defined before this.
The limitation criterion may be represented e.g. as a function including the said electric quantity as a variable; on the other hand, the limitation criterion may be represented e.g. in tabular or graphic form with respect to the said electric quantity. As a limitation criterion, it is possible to use e.g. the longest total time allowed for overloading of the component, or the recovery time required as a whole for recovery from overloading. The limitation criterion may be represented linearly or non-linearly with respect to the electric quantity constituting a load on the component. The limitation criterion may be defined repeatedly; likewise, the instantaneous load capacity of the component may be estimated from a repeatedly defined limitation criterion, in which case the loading history of the component is also taken into account in the estimation of instantaneous load capacity of the component. Thus, as the estimation of instantaneous load capacity of the component becomes more accurate, the protection of the component against overloading is also improved. Due to the improved overload protection, the component can momentarily be subjected to a load exceeding the nominal load. This is useful especially in systems where the component is exposed to a temporally varying load, because in this case the component need not necessarily be rated for the highest instantaneous load, so it is possible to use components of a lower power handling capacity. The components to be protected may include e.g. so-called slow fuses, or e.g. different power semiconductors, resistors, inductors, capacitors and transformers. In the case of a slow fuse, heating-up is reduced by increasing the heating-up time constant of the component, e.g. by adding sand or some other heat-retarding material around the fuse wire.
In an embodiment of the invention, the arrangement comprises a representation of the time to failure of the component, wherein the time to failure is represented with respect to an electric quantity constituting a load on the component. “Time to failure” refers to the total time that the component will typically tolerate a given loading, so that the loading would finally lead to failure of the component. The electric quantity constituting a load on the component and the corresponding time to failure are defined repeatedly, and the estimate of instantaneous load capacity of the component is determined on the basis of both the time to failure defined substantially at the moment of estimation and the times to failure defined previously. The protection of the component against overloading is thus improved.
According to the invention, the load capacity of the power supply circuit component to be protected can be determined without separate measurement of the temperature of the component. Thus, as the number of temperature sensors is reduced, the overall system is simplified and the reliability of the system improved.
Different systems subject to varying loads include e.g. transportation systems, such as a passenger or freight elevator system, escalator system, passenger conveyor system, roller elevator system, crane system, vehicle system or a conveyor system for conveying goods and/or raw materials. The aforesaid elevator system may be a system with or without machine room. The elevator system may also be a counterweighted or counterweightless system.
The transportation system of the invention comprises an arrangement for protecting a fuse in the power supply to the transportation system, said arrangement comprising determination of the current flowing through the fuse, which fuse current is determined repeatedly while the fuse is exposed to a load. The arrangement also comprises estimation of instantaneous load capacity of the fuse, which estimation of instantaneous load capacity is performed using a limitation criterion set for the load capacity of the fuse. This limitation criterion indicates the longest possible operating time of the fuse under a given loading condition. For the limitation criterion, a representation with respect to the fuse current is provided, and a limitation criterion corresponding to the defined fuse current is derived repeatedly from the said representation while the fuse is exposed to a load. The estimate of instantaneous load capacity of the fuse is thus determined on the basis of both the limitation criterion defined substantially at the instant of estimation and the limitation criteria defined before this. The fuse current is adapted to be limited to a given boundary current value, and this boundary current value is determined according to the estimated load capacity of the fuse. In an embodiment of the invention, power exceeding the limited current handling capacity of the fuse is adapted to be consumed in a resistor connected to the power supply circuit of the transportation system.
When the fuse in the power supply to the transportation system is thus protected by the method of the invention, a fuse rating below the required instantaneous maximum loading can be selected for the building. As the fuse rating has a substantial effect on the costs of power supply to the building, the invention thus makes it possible to achieve significant savings.
In an embodiment of the invention, the power supply circuit comprises a control function, and this power supply control function is adapted to limit the current flowing through a component in the power supply circuit to a given boundary current value, said boundary current value being determined according to an estimated instantaneous load capacity of the component. The boundary current value can be varied in accordance with the instantaneous estimate of the load capacity of the component. For example, the current flowing in the power supply circuit of a transportation system can thus be limited to the boundary current value allowed at a given instant of time, and the boundary value can be varied in response to load capacity and/or to a change in load capacity. This also allows the component to be subjected to an instantaneous load exceeding the nominal load.
In an embodiment of the invention, the estimation of load capacity of the component is implemented using a component recovery time corresponding to the value of the electric quantity constituting a load on the component. The reason for this is that, when the loading on the component is reduced to a level below a given boundary loading value, the component begins to recover. The component temperature starts falling at a rate determined by the thermal time constant, and the recovery takes place the faster the lower is the loading during recovery. Therefore, as the component is recovering/cooling down, the estimate of instantaneous load capacity of the component starts rising correspondingly, and thus the determination of component recovery time can be utilized to achieve a more accurate estimate of the instantaneous value of the load capacity of the component. According to the invention, the recovery time is so defined that it corresponds to the total time after which the component will be considered as having completely recovered from the strain preceding recovery if the electric quantity constituting a load on the component remains constant throughout the recovery period.
According to one or more embodiments of the invention, the estimation of instantaneous load capacity is performed using additionally a second limitation criterion set for the load capacity of the component, this second limitation criterion indicating the recovery time of the component under a given loading condition. The recovery of the component can thus be determined, and when the component is recovering, its momentary overload capacity increases.
An elevator system according to the invention comprises one of the above-introduced arrangements for protecting a component in the power supply circuit of the elevator system.
According to one or more embodiments of the invention, data indicating the instantaneous load capacity of the power supply circuit component is arranged to be transmitted to an elevator maintenance center. The data indicating the instantaneous load capacity of the power supply circuit component can thus also be used e.g. for remote control and/or maintenance of the elevator.
In the following, the invention will be described in detail by referring to embodiment examples and the attached drawings, wherein
a is a representation of component failure time and component recovery time according to the invention
b represents the instantaneous load capacity of a component in an embodiment of the invention
a shows a representation 4, 4′ according to the invention which is used for the estimation of instantaneous load capacity of a component 2. The component time to failure 5, 5′, 5″ and correspondingly the component recovery time 13, 13′ are represented with respect to the current I 6, 6′, 6″, 6′″, 6″″ flowing through the component. Here the representation has been made for a so-called slow fuse, which is the type of fuse used for the interruption of overcurrent e.g. in the electricity connection of a building, but a corresponding representation 4 of time to failure 5, 5′, 5″ and/or a representation 4′ of component recovery time 13, 13′ can also be made for other power supply circuit components for which the time elapsing until component failure and/or recovery can be determined e.g. experimentally or on the basis of the material and/or thermal time constant of the component with respect to the electric quantity constituting a load on the component.
From characteristic 4 in
b represents the instantaneous load capacity 9, 9′ of a slow fuse as a function of time t when the load capacity 9, 9′ is estimated in the manner presented in the block diagram in
The characteristic 4′ for the fuse recovery time 13, 13′ can also be replaced by a given standard value of recovery time, in which case the duration of recovery of the component is not determined quite as accurately but the calculation of instantaneous load capacity is simplified. In this case, using a safety margin, a recovery time is selected that is long enough to ensure that recovery from over-loading has taken place before the instantaneous load capacity of the component is restored to value 1.
In
The arrangement comprises estimation of the load capacity of the fuse 2. The instantaneous load capacity 9, 9′ of the fuse is estimated e.g. in the manner described in the embodiment examples represented by
Connected to the intermediate circuit of the frequency converter 18, between the positive 19 and negative 19′ intermediate circuit rails, is a series circuit of a power resistor 14 and a controllable switch 22. Power exceeding the limited current handling capacity of the fuse 2 during motor braking of the electric motor 20 has been adapted to be consumed in the aforesaid power resistor 14.
The transportation system power supply arrangement presented in
The power returned to the electricity network 17 also flows through the power supply fuse 2, and consequently the fuse in the electricity network phase connected to the mains inverter 21 is subjected to a greater load than the fuses in the other phases. For this reason, the elevator system is provided with an arrangement according to the invention for protecting a power supply fuse. The instantaneous load capacity of the fuse in the aforesaid electricity network 17 phase connected to the mains inverter 21 is determined e.g. in the manner described in the embodiment examples of
In an embodiment of the invention, the motion of the transportation apparatus 23, such as the velocity, acceleration and/or deceleration of the elevator car, is limited in accordance with the estimated load capacity 9, 9′ of the electricity supply fuse 2.
The invention is not exclusively limited to the above-described embodiment examples, but many variations are possible within the scope of the inventive concept defined in the claims.
The component failure time and/or recovery time may be affected e.g. by ambient temperature and possible cooling of the component.
The motor driving the transportation apparatus may be a rotary motor or also a linear motor, in which case the movable rotor may be attached directly to the transportation apparatus.
Some of the power returning to the frequency converter during motor braking may also be utilized for satisfying the power requirement of the electrification of the transportation system.
The magnitude of the power flow from the motor driving the transportation apparatus into the frequency converter's intermediate circuit can also be determined e.g. on the basis of measurements of motor current and/or voltage.
Number | Date | Country | Kind |
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20080667 | Dec 2008 | FI | national |
This application is a Continuation of PCT International Application No. PCT/FI2009/000101 filed on Dec. 3, 2009, which claims the benefit of Patent Application No. 20080667 filed in Finland, on Dec. 19, 2008. The entire contents of all of the above applications is hereby incorporated by reference into the present application.
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Number | Date | Country | |
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20110235226 A1 | Sep 2011 | US |
Number | Date | Country | |
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Parent | PCT/FI2009/000101 | Dec 2009 | US |
Child | 13155167 | US |