The present invention relates to a portable casing for land surveying applications (particularly for transporting a surveying instrument, or machine, configured to perform land surveying measurements) and a method for controlling charging of a plurality of batteries in such a portable casing.
Generally, land surveying involves the determination of terrestrial (e.g., two-dimensional, 2D, or three-dimensional, 3D) positions of points and the determination of distances and angles between these points. Land surveying may include 3D scanning by taking measurements of a scene such as a building, a worksite, and surroundings to obtain a 3D cloud of measured points (e.g., based on measured distance and angle from the surveying instrument to these points) over vertical and azimuthal angular limits.
For this purpose, a surveyor may use a surveying instrument, such as a robotic total station integrating an electronic distance measurement unit (EDM unit) with a movable centre unit (or telescope) for rotation about at least two axes (typically a trunnion, or horizontal, axis and an azimuth, or vertical, axis). The centre unit may be mounted on an alidade for rotation about a first axis (e.g., the trunnion axis) and the alidade may be mounted on a base for rotation about a second axis (e.g., the azimuth axis) intersecting (e.g., being orthogonal to) the first axis, such that the instrument optical axis is rotatable about a rotation point. The surveying instrument may also be a geodetic scanner typically including a rotating mirror to scan the optical axis of the instrument at a high speed in a vertical direction. The rotating mirror may be mounted on a scan head rotating azimuthally about another axis at low speed.
For operation of these surveying instruments such as, for example, for driving motors causing motion of their rotatable parts (such as e.g., the centre unit, alidade, rotating mirror, or scan head of these instruments), electrical power is necessary. However, in many scenarios, land surveying is to be performed at places where mains electricity is not available and electrical power needs to be provided to the surveying instruments using a battery housed in a part of the surveying instrument.
In addition, land surveying may involve long-time measurements, such as for example scanning of larger worksites or tracking of targets, or a long sequence of (e.g., programmed) measurements during which the surveying instrument should preferably not run out of electrical power. For such large-scale and/or long-term mapping, measurement or tracking work, a surveyor needs to bring extra batteries to the field to replace discharged batteries and ensure that the instrument will not run out of electrical power. Further, surveyors often want a fully charged battery at every setup to minimize the risk of running out of power in the middle of a measurement, why a half full battery often is replaced by a fully charged battery and the half full battery is brought to the office for charging.
In view of the present situation, battery management for land surveying applications is not optimized and there is still a need for new solutions facilitating the handling of batteries and/or improving management of battery resources for land surveying applications.
The present disclosure seeks to provide at least some embodiments that overcome at least some of the above-mentioned drawbacks. More specifically, the present disclosure aims at providing at least some embodiments offering an improved management of battery resources for land surveying applications. To achieve this, a portable casing for transporting a surveying instrument and a method having the features as defined in the independent claims are provided. Further advantageous embodiments of the present disclosure are defined in the dependent claims.
According to a first aspect, there is provided a portable casing for a surveying instrument, wherein the portable casing includes a primary compartment for lodging the surveying instrument and a plurality of secondary compartments for housing a plurality of rechargeable batteries. The portable casing also includes a charging unit arranged in the casing and electrically connected to the plurality of compartments for transferring electrical energy to and/or from the plurality of rechargeable batteries. A control unit of the portable casing is configured to obtain information about the state of charge of each of the plurality of rechargeable batteries arranged in the plurality of secondary compartments, and control, based on the obtained information, an inter-charging function of the charging unit to cause, among batteries of the plurality of rechargeable batteries that have a state of charge below a first threshold, a lesser discharged battery to receive electrical energy from at least one more discharged battery.
Embodiments according to the first aspect of the present disclosure provide a solution for battery management integrated in the casing used for transporting the surveying instrument. Rather than only providing compartments or sections within the casing at which batteries may be arranged for being transported to a worksite together with the surveying instrument, an inter-charging function for improving battery management is included in the portable casing disclosed herein. With this inter-charging function, a battery that has a higher state of charge (i.e., a lesser discharged battery) receives electrical energy from a battery that has a lower state of charge (i.e., a more discharged battery). Hence, the present embodiments provide a portable casing with a “top-up” charging function such that a lesser discharged battery becomes even more charged. Phrased differently, a more discharged battery is, or more discharged batteries are, discharged even more to the benefit of a lesser discharged battery, or lesser discharged batteries. This is beneficial for land surveying applications, particularly for long-time measurements or a long sequence of measurements, for which it is preferable to mount an even more charged battery in the surveying instrument. Accordingly, the surveying instrument may be provided with power during a longer period of time, without the need of replacing the battery.
Embodiments according to the first aspect of the present disclosure provides a portable casing including a charging unit with inter-charging function in which electrical energy from batteries having a lower (e.g., a too low) state of charge is used to charge other batteries having a higher state of charge to an even higher capacity. As mentioned above, with the embodiments according to the first aspect of the present disclosure, the need to often change battery and bring an excessive number of batteries to the field is removed, or at least reduced, since the operator is provided with at least one battery that is more charged, and preferably charged as much as possible.
The first threshold may for example be 100%, in which case all batteries located in the plurality of secondary compartments may in principle be involved in the inter-charging function. However, in other examples, the first threshold may be 80% or 90%, in which case only the batteries having a state of charge lower than 80% or 90%, respectively, may be involved. In these examples, it may be considered that batteries having a state of charge above a certain first threshold (such as e.g., 80% or 90%) are sufficiently charged for long-time measurements (or a long sequence of measurements) and/or that charging such batteries to an even higher level of state of charge might damage the health of the batteries.
According to the present embodiments, if three batteries with respective states of charge of 30%, 70% and 90% are arranged in the casing and the first threshold is 80%, then the charging unit is configured to transfer electrical energy from the battery having a state of charge of 30% to the battery having a state of charge of 70%.
In case there were four batteries and two of them would have a state of charge of 70%, the charging unit could arbitrarily select one of these two batteries for transferring electrical energy from the battery having a lower state of charge (30% in the above example) to the selected battery.
In some implementations, the batteries having a state of charge above a second threshold may belong to a first group and the batteries having a state of charge below the second threshold may belong to a second group. The control unit may then be configured to cause a battery of the second group to provide electrical energy to a battery of the first group. As a result, the batteries of the first group will become even more charged while the batteries of the second group will become even less charged. Hence, rather than having a plurality of batteries at different medium charging levels, wherein none of them may be sufficiently charged to electrically support the complete operation of a long sequence of measurements by a surveying instrument, the batteries of the first group will reach a higher capacity level and may thereby be used for such applications.
In some implementations, the control unit may be configured to cause the least discharged battery to receive electrical energy from the other batteries of the plurality of batteries arranged in the portable casing. Accordingly, the control unit may be configured to determine the least discharged battery and provide this battery with electrical energy from the other batteries.
In some implementations, the control unit may be configured to cause the most discharged battery to provide electrical energy to the least discharged battery. Still based on the purpose of obtaining batteries having a higher (or highest) state of charge in the portable casing and sacrificing the more discharged batteries, which would not be selected for long time measurements or long sequence of measurements, the control unit may, in the present implementations, select the most discharged battery and transfer the electrical energy of this most discharged battery to the least discharged battery. In an example in which only two batteries are arranged in the portable casing, the more discharged battery would provide electrical energy to the less discharged battery. In general, considering examples with more than two batteries at different states of charge, the control unit may cause the most discharged battery to provide its electrical energy to the least discharged battery.
In some implementations, the control unit may be configured to cause the lesser discharged battery to receive electrical energy from the more discharged battery until a discharging threshold for the state of charge of the more discharged battery is reached or until a charging threshold for the state of charge of the lesser discharged battery is reached.
For example, the control unit may be configured such that the more discharged battery is not discharged below a state of charge of 10%. Using a discharging threshold for the batteries providing their electrical energy to anther battery ensures that they are not discharged below a level at which they may be damaged, or at which they may not be recharged (at all, or properly, i.e., within a reasonable time frame).
Further, the control unit may be configured such that a lesser discharged battery, such as for example the least discharged battery, is not charged above a charging threshold, e.g., 80% or 90%, since charging a battery above a certain level may also be detrimental for its operational lifetime. It will be appreciated that the charging threshold may be the same as the first threshold mentioned above.
In some implementations, the control unit may be configured to cause the second most discharged battery to provide electrical energy to the least discharged battery on a condition that the state of charge of the most discharged battery has reached the discharging threshold and the state of charge of the least discharged battery has not reached the charging threshold. Phrased differently, once the most discharged battery has been emptied, the control unit is configured to select the second most discharged battery to provide electrical energy to the least discharged battery, should it still require electrical energy, i.e., if the state of charge of the least discharged battery is still below the charging threshold.
In some implementations, the portable casing may further comprise a connector for electrical connection of the charging unit to a power-driven unit of the surveying instrument. On a condition that the charging unit is connected to the power-driven unit, the control unit may then be configured to control the charging unit to supply electrical energy to the power-driven unit from the batteries having the lowest states of charge first and subsequently from a less discharged battery. In other words, although the present embodiments provide the possibility for a surveyor to install a battery arranged in the portable casing, such as the least discharged battery, in the surveying instrument for performing a measurement, the portable casing may also be equipped with a connector, or connecting means, for directly connecting the portable casing to the surveying instrument and thereby provide electrical power to the surveying instrument.
In such a situation, still for the purpose of keeping a battery that is charged as much as possible in the portable casing, the control unit may, in some implementations, be configured to first use power from the batteries having the lowest states of charge and only subsequently use the more charged batteries (or less discharged ones), and particularly use the least discharged battery as a last resource of power.
The connector or connecting means may include one of a physical connector and/or a wireless/inductive charging connector. The physical connector and the wireless/inductive charging connector may for example be arranged in a side cover of the portable casing.
The control unit may be configured to first cause the most discharged battery to provide electrical energy to the power-driven unit of the surveying instrument until a discharging threshold (which may be the same as the discharging threshold already mentioned above) for the state of charge of the most discharged battery is reached. It will be appreciated that the control unit may then be configured to cause the second most discharged battery to provide electrical energy to the power-driven unit of the surveying instrument and so forth.
The portable casing may further comprise a terminal for electrical connection of the charging unit to a power outlet of an external power source, such as for example a power grid (or mains electricity) or a vehicle battery, and/or a photovoltaic system arranged on at least one side of the portable casing. The control unit may then be configured to cause the charging unit to transfer electrical energy received at the charging unit from the external power source, and/or the photovoltaic system, to the plurality of batteries for charging. As an example, the portable casing may be equipped with a power outlet for connection in a vehicle so that the batteries get charged while driving to e.g., a worksite. The portable casing may then work as a charger for the batteries.
The control unit of the portable casing may be configured to prioritize charging of the plurality of batteries from the external power source, and/or the photovoltaic system, based on the respective states of charge of the batteries. For example, the control unit may be configured to cause less discharged batteries to be charged before more discharged batteries.
Diverse functions may be implemented in the portable casing. For example, the portable casing may comprise a display unit configured to display at least one of: an indication of the respective states of charge of the plurality of batteries arranged in the compartments, the state of charge of a battery mounted in the surveying instrument (for example on a condition that the portable casing is electrically connected to the surveying instrument), an indication of which battery of the plurality of batteries has the highest state of charge, a selection mechanism for activation/deactivation of the inter-charging function as described above, and/or an indication that the state of charge of a battery is below a predetermined threshold, such as for example 25%.
According to a second aspect, a method for controlling charging of a plurality of batteries arranged in a portable casing for transporting a surveying instrument is provided. The method comprises obtaining information about the state of charge of each of the plurality of batteries, and controlling, based on the obtained information, an inter-charging function of the portable casing to cause, among batteries of the plurality of batteries that have a state of charge below a first threshold, a lesser discharged battery to receive electrical energy from at least one more discharged battery.
The technical effects and advantages discussed above in connection to the first aspect of the present disclosure and its various implementations apply also to the second aspect of the present disclosure. The different embodiments and implementations described above with reference to the first aspect of the present disclosure apply also the second aspect.
For example, the batteries having a state of charge above a second threshold may belong to a first group and the batteries having a state of charge below the second threshold may belong to a second group. The controlling may then include causing a battery of the second group to provide electrical energy to a battery of the first group.
Further, the controlling may include causing the least discharged battery to receive electrical energy from the other batteries of the plurality of batteries arranged in the casing.
The controlling may also include causing the more discharged battery to provide electrical energy to the lesser discharged battery until a discharging threshold for the state of charge of the more discharged battery is reached or until a charging threshold for the state of charge of the lesser discharged battery is reached.
The controlling may include causing the second most discharged battery to provide electrical energy to the least discharged battery on a condition that the state of charge of the most discharged battery has reached the charging threshold and the state of charge of the least discharged battery has not reached the discharging threshold.
Further, on a condition that the portable casing is electrically connected for providing power to a power-driven unit of the surveying instrument, electrical energy may be supplied to the power-driven unit from the batteries having the lowest states of charge first and subsequently from a less discharged battery.
Further, the method may comprise causing the most discharged battery to provide electrical energy to the power-driven unit of the surveying instrument until a discharging threshold for the state of charge of the most discharged battery is reached.
The method may further comprise causing charging of the plurality of batteries by transferring, to the plurality of batteries, electrical energy received at the portable casing from an external power source and/or a photovoltaic system of the portable casing. In this respect, the charging may include prioritizing charging of the plurality of batteries from the external power source, and/or the photovoltaic system, based on the respective states of charge of the batteries.
As for the first aspect of the present disclosure, the method may comprise displaying at least one of: an indication of the respective states of charge of the plurality of batteries arranged in the portable casing, the state of charge of a battery mounted in the surveying instrument (on a condition that the portable casing is electrically connected to the surveying instrument), an indication of which battery of the plurality of batteries has the highest state of charge, and/or an indication that the state of charge of a battery is below a predetermined threshold.
The present disclosure relates to all possible combinations of features recited in the claims and in the preceding embodiments. Further objects and advantages of the various embodiments of the present disclosure will be described below by means of exemplifying embodiments.
One or more embodiments will be described, by way of example only, and with reference to the following figures (which should not be considered as being to scale), in which:
Whilst the invention is susceptible to various modifications and alternative forms, specific embodiments are shown by way of example in the drawings as herein described in detail. It should be understood, however, that the detailed description herein and the drawings attached hereto are not intended to limit the invention to the particular form disclosed. Rather, the intention is to cover all modifications, equivalents, and alternatives falling within the scope of the appended claims.
Any reference to prior art documents or comparative examples in this specification is not to be considered as an admission that such prior art is widely known or forms part of the common general knowledge in the field.
As used in this specification, the words “comprise”, “comprising”, and similar words are not to be interpreted in the exclusive or exhaustive sense. In other words, they are intended to mean “including, but not limited to”.
The present invention is described in the following by way of a number of illustrative examples. It will be appreciated that these examples are provided for illustration and explanation only and are not intended to be limiting on the scope of the present invention. Instead, the scope of the present invention is to be defined by the appended claims. Furthermore, although the examples may be presented in the form of individual embodiments, it will be recognised that the invention also covers combinations of the embodiments described herein.
Such 3D scanning and other tasks (or sequence of tasks) to be run by a surveying instrument require that the surveying instrument is provided with power during a relatively long time. However, such tasks are most often performed at places where mains electricity is not available. The surveying instrument is therefore equipped with a cassette in which a battery is lodged for providing electrical power to the surveying instrument. When setting up the instrument for a new measurement, or a series of measurements, the surveyor usually introduces a new, fully charged, battery in the surveying instrument. Although not completely empty, batteries that have relatively low states of charge are not used by the surveyors. These batteries are brought back to the office for recharging.
With reference to
As shown in
In addition to the primary compartment 220, the portable casing 200 may also include a plurality of secondary compartments 230 for housing a plurality of rechargeable batteries 235. In the example shown in
The portable casing 200 also includes a charging unit 240 which is electrically connected to the plurality of secondary compartments 230. The compartments, or inserts, in which the batteries 235 are placed may for example be equipped with electrical connections at their bottom such that the batteries are electrically connected to the charging unit 240 via these electrical connections. These electrical connections may be used for reading the respective states of charge of the batteries placed in the secondary compartments 230. Further, the electrical connections may be used for transferring electrical energy to and/or from the plurality of rechargeable batteries. For example, electrical energy may be transferred from one battery to another or from the mains electricity to one or more of the rechargeable batteries.
A control unit 250 of the portable casing 200 is configured to obtain information about the state of charge of each of the plurality of rechargeable batteries 235 arranged in the plurality of secondary compartments 230, and control, based on the obtained information, an inter-charging function of the charging unit 240 to cause, among batteries of the plurality of rechargeable batteries that have a state of charge below a first threshold, a lesser discharged battery to receive electrical energy from at least one more discharged battery.
By way of example, a scenario with four rechargeable batteries placed in the portable casing 200 is herein considered. A first battery has a state of charge (SoC) of 90%, while the second, third and fourth batteries have respective levels of charge (or SoC) of 70%, 40% and 25%. If the first threshold is set at, e.g., 80%, then the first battery will not be involved in the control provided by the control unit 250. In other words, the first battery will neither be charged nor discharged. If the first threshold is set at, e.g., 95% or 100%, then all four batteries will be involved.
Assuming that the first threshold is set at 95%, then the control unit 250 may be configured to cause the transfer of electrical energy from the batteries having lower states of charge (SoC), such as, for example, the third and fourth batteries having SoC of 40% and 25%, to the batteries having higher states of charge, i.e., the first and second batteries having SoC of 90% and 70%, respectively. In some implementations, the control unit 250 may be configured to group the batteries having a SoC above a second threshold, e.g., 50%, in a first group and the batteries having a SoC below the second threshold in a second group such that a battery of the second group (for example the third or fourth battery in the present example) is caused to provide electrical energy to a battery of the first group (for example the first or second battery).
In some implementations, the control unit 250 may be configured to cause the least discharged battery, i.e., the first battery having a SoC of 90%, to receive electrical energy from the other batteries arranged in the portable casing 200. Preferably, the control unit 250 may be configured to cause the most discharged battery, i.e., the fourth battery having a SoC of 25% in the present example, to provide electrical energy to the least discharged battery, i.e., the first battery.
Further, it will be appreciated that the control unit 250 may be configured to prevent the first battery from being charged above a certain charging threshold, which may be the same as the first threshold, i.e., 95% in the present example, since this may degrade the battery performance. Hence, should the SoC of the first battery reach 95%, the control unit may be configured to stop charging of the first battery and for example cause the fourth battery to transfer electrical energy to the second battery instead.
In addition, it will be appreciated that the control unit 250 may be configured to prevent the fourth battery from reaching a SoC below a certain discharging threshold, such as e.g. 10%, as this may otherwise degrade the battery. Hence, should the SoC of the fourth battery reach a SoC of 10%, the control unit 250 may be configured to stop the discharge of the fourth battery. Should the first battery still have a SoC below the charging threshold of 95%, the control unit 250 may then cause the second most discharged battery, i.e., the third battery having a SoC of 40% in the present example, to transfer electrical energy to the first battery.
The control unit 250 and the charging unit 240 provide therefore an inter-charging function wherein, instead of equalizing the SoC of the batteries, batteries having higher SoC, e.g., the battery having the highest SoC (as long as it is below a certain threshold), receive electrical energy from batteries having lower SoC, and in particular the most discharged battery first (as long as it is not below a discharging threshold).
Although described as two units, the charging unit and the control unit may in some applications be implemented in a single entity.
The portable casing 200 may also be equipped with a connector 260 for electrical connection of the charging unit to the surveying instrument, and in particular to a power-driven unit of the surveying instrument. This implementation will be further described below with reference to
The portable casing 200 may further comprise a terminal 290 for electrical connection of the charging unit 240 to a power outlet of an external power source, such as, for example, a power grid (or mains electricity) or a vehicle battery, and/or a photovoltaic system arranged on at least one side of the portable casing 200. As illustrated in
The control unit 250 may then be configured to cause the charging, via the charging unit 240, of the batteries placed in the portable casing 200 by transferring electrical energy received at the charging unit 240 from the external power source, and/or the photovoltaic system, to the plurality of batteries. In some implementations, the control unit 250 of the portable casing 200 may be configured to prioritize charging of the plurality of batteries 235 from the external power source, and/or the photovoltaic system, based on the respective states of charge of the batteries 235.
The portable casing 200 may also be equipped with a display unit 280 configured to display information relating to the batteries being placed within the portable casing 200. As shown in
Although
The display unit may for example be a touchscreen, or be provided together with a selection mechanism, for activation/deactivation of the inter-charging function as described above. The display unit may also be configured to indicate that the state of charge of a battery is below a predetermined threshold, such as for example 25%.
With reference to
The method 3000 includes, at 3100, obtaining information about the state of charge of each of the plurality of batteries, and, at 3200, controlling, based on the obtained information, an inter-charging function of the portable casing to cause, among batteries of the plurality of batteries that have a state of charge below a first threshold, a lesser discharged battery to receive electrical energy from at least one more discharged battery.
The method 3000 can be implemented in the control unit 250 of the portable casing 200 described with reference to
In addition, in some implementations, the charging unit may be electrically connected to the first compartment for connection of the charging unit to a battery installed in the surveying instrument lodged in the primary compartment. The control unit may then be configured to control the inter-charging function among the batteries arranged in the secondary compartment and the battery arranged in the primary compartment.
With reference to
In the present example, the battery denoted 435a (also referred to as the first battery in the following) is represented as having a higher state of charge than the battery denoted 435b (also referred to as the second battery in the following). The batteries 435a and 435b may be connected to the charging unit (or battery charger) 440, for example, and if necessary, via a DC/DC converter (not shown) suitable for adapting the DC current and/or DC voltage to be transferred between the batteries 435a and 435b. Alternatively, the charging unit 440 may itself include one or more DC/DC converters for adapting the DC current and/or DC voltage to a level suitable for the batteries 435a and 435b.
The batteries 435a and 435b (or any sensor connected to the batteries) may also communicate, for example via the SMBUS 454, their respective states of charge to the control unit 450, for example by a measurement of their respective capacitance (such as via a measurement of a voltage).
Further,
Further, the circuitry shown in
Further, the control unit 450 may cause the charging unit 440 to provide electrical power to a battery from another battery arranged in one of the secondary compartments, such as for example an exchange of power between the batteries 435a and 435b. In this respect, it will be appreciated that the switching arrangement 442 depicted in
The control unit 450 may control the switching arrangement 452 for causing the portable casing to provide power to the surveying instrument 405 from a specific battery installed in the portable casing. In the present example, the control unit 450 may be configured to control the switching arrangement 452 such that electrical power is provided first from the lower charged battery 435b (i.e., the second battery) and then from the higher charged battery (i.e., the first battery).
The electrical circuit or electrical connection of the elements of the portable casing shown in
Further,
Further, the switches or switching arrangements 442 and 452 may be connected to each other or integrated to each other. The switches may also be equipped with further poles so that they are, in some states, not connected to any battery. The switches are controlled by the control unit 450 in accordance with the methods as described in any of the embodiments disclosed herein. Further, the control unit 450 may be configured to control the charging of the batteries so as to avoid, or at least reduce, any risk of short circuit.
With reference to
On a condition that the portable casing 500 (and in particular its charging unit) is connected to the surveying instrument 505, the control unit of the portable casing may be configured to control the charging unit to supply electrical energy to the surveying instrument (and in particular a power-driven unit of the surveying instrument 505) from the batteries having the lowest states of charge first and subsequently from a less discharged battery.
The control unit of the portable casing 500 may, in some implementations, be configured to first use power from the batteries having the lowest states of charge and only subsequently use the more charged batteries (or less discharged ones), and particularly use the least discharged battery as a last resource of power.
Although the connector 560 may be arranged within the portable casing, in which case the portable casing 500 might need to remain opened, unless a passage is formed in the casing for introducing the power cable 565, the connector 560 may advantageously be positioned at an external side, such as e.g., the box cover, of the portable casing, in which case the portable casing can remain closed. The connector 560 (or connecting means) may include a physical connector, as shown in
The control unit may be configured to first cause the most discharged battery to provide electrical energy to the power-driven unit of the surveying instrument until a discharging threshold (which may be the same as the discharging threshold already mentioned above) for the state of charge of the most discharged battery is reached. It will be appreciated that the control unit may then be configured to cause the second most discharged battery to provide electrical energy to the power-driven unit of the surveying instrument and so forth.
It will be appreciated that, unless explicitly stated otherwise, the examples shown in different figures may be combined, and elements having like reference numerals in different figures may be the same or similar to each other. In any event, it is intended that the foregoing description not to be limiting upon the scope of the invention, and that the invention be defined only by the scope of the following claims.
The present application is a continuation of International Application No. PCT/EP2022/067063, filed Jun. 22, 2022, the entire contents of which are incorporated herein by reference in their entirety for all purposes.
Number | Date | Country | |
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Parent | PCT/EP2022/067063 | Jun 2022 | WO |
Child | 18914982 | US |