NZ759229B2 - Heat dissipation structure for motor - Google Patents
Heat dissipation structure for motorInfo
- Publication number
- NZ759229B2 NZ759229B2 NZ759207A NZ75920719A NZ759229B2 NZ 759229 B2 NZ759229 B2 NZ 759229B2 NZ 759207 A NZ759207 A NZ 759207A NZ 75920719 A NZ75920719 A NZ 75920719A NZ 759229 B2 NZ759229 B2 NZ 759229B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- vehicle
- data
- route
- agricultural
- field
- Prior art date
Links
- 230000017525 heat dissipation Effects 0.000 title 1
- 239000000463 material Substances 0.000 claims abstract description 54
- 238000004891 communication Methods 0.000 abstract description 4
- 239000004744 fabric Substances 0.000 abstract 2
- 239000012530 fluid Substances 0.000 abstract 2
- 229920001296 polysiloxane Polymers 0.000 abstract 2
- 229920002725 thermoplastic elastomer Polymers 0.000 abstract 2
- 230000029058 respiratory gaseous exchange Effects 0.000 abstract 1
- 238000000034 method Methods 0.000 description 16
- 239000000446 fuel Substances 0.000 description 6
- 238000012545 processing Methods 0.000 description 5
- 230000008901 benefit Effects 0.000 description 3
- 238000004590 computer program Methods 0.000 description 3
- 238000004566 IR spectroscopy Methods 0.000 description 2
- 239000004459 forage Substances 0.000 description 2
- 238000013507 mapping Methods 0.000 description 2
- 238000005259 measurement Methods 0.000 description 2
- 239000010902 straw Substances 0.000 description 2
- 238000012546 transfer Methods 0.000 description 2
- 230000001052 transient effect Effects 0.000 description 2
- 241001124569 Lycaenidae Species 0.000 description 1
- 241000209140 Triticum Species 0.000 description 1
- 235000021307 Triticum Nutrition 0.000 description 1
- 230000001133 acceleration Effects 0.000 description 1
- 230000006835 compression Effects 0.000 description 1
- 238000007906 compression Methods 0.000 description 1
- 238000011217 control strategy Methods 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 230000006870 function Effects 0.000 description 1
- 238000003306 harvesting Methods 0.000 description 1
- 230000007774 longterm Effects 0.000 description 1
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D29/00—Details, component parts, or accessories
- F04D29/26—Rotors specially for elastic fluids
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
- F05D2240/00—Components
- F05D2240/20—Rotors
- F05D2240/30—Characteristics of rotor blades, i.e. of any element transforming dynamic fluid energy to or from rotational energy and being attached to a rotor
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K2205/00—Specific aspects not provided for in the other groups of this subclass relating to casings, enclosures, supports
- H02K2205/09—Machines characterised by drain passages or by venting, breathing or pressure compensating means
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K5/00—Casings; Enclosures; Supports
- H02K5/04—Casings or enclosures characterised by the shape, form or construction thereof
- H02K5/16—Means for supporting bearings, e.g. insulating supports or means for fitting bearings in the bearing-shields
- H02K5/161—Means for supporting bearings, e.g. insulating supports or means for fitting bearings in the bearing-shields radially supporting the rotary shaft at both ends of the rotor
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K5/00—Casings; Enclosures; Supports
- H02K5/04—Casings or enclosures characterised by the shape, form or construction thereof
- H02K5/20—Casings or enclosures characterised by the shape, form or construction thereof with channels or ducts for flow of cooling medium
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K9/00—Arrangements for cooling or ventilating
- H02K9/02—Arrangements for cooling or ventilating by ambient air flowing through the machine
- H02K9/04—Arrangements for cooling or ventilating by ambient air flowing through the machine having means for generating a flow of cooling medium
- H02K9/06—Arrangements for cooling or ventilating by ambient air flowing through the machine having means for generating a flow of cooling medium with fans or impellers driven by the machine shaft
Abstract
mask system (10) for supplying air from a source of air at positive pressure to a patient for treatment of sleep disordered breathing, the mask system including an interfacing structure (20) configured to engage and seal against an underside of a patient's nose, two inlet conduits (42) detachably connectable to the interfacing structure and adapted to deliver the supply of air to the interfacing structure, and a back strap (60) disposed between the two inlet conduits, the back strap being adapted to extend across a rear of the patient’s head in use. The interfacing structure includes at least one orifice formed therein to deliver the air to the patient’s airways, the at least one orifice being configured to be positioned externally of the patient’s airways and in fluid communication therewith in use. Each inlet conduit is adapted to extend from an upper portion of the patient's head, along a respective side of the patient's face between the patient's eye and ear, and to the interfacing structure. Each inlet conduit has a layered structure including an inner layer defining a passageway for conveying the air to the interfacing structure, the inner layer comprising a thermoplastic elastomer or a silicone material and an outer fabric layer configured to cover the inner layer and to, in use, contact the patient’s skin. connectable to the interfacing structure and adapted to deliver the supply of air to the interfacing structure, and a back strap (60) disposed between the two inlet conduits, the back strap being adapted to extend across a rear of the patient’s head in use. The interfacing structure includes at least one orifice formed therein to deliver the air to the patient’s airways, the at least one orifice being configured to be positioned externally of the patient’s airways and in fluid communication therewith in use. Each inlet conduit is adapted to extend from an upper portion of the patient's head, along a respective side of the patient's face between the patient's eye and ear, and to the interfacing structure. Each inlet conduit has a layered structure including an inner layer defining a passageway for conveying the air to the interfacing structure, the inner layer comprising a thermoplastic elastomer or a silicone material and an outer fabric layer configured to cover the inner layer and to, in use, contact the patient’s skin.
Description
AN AGRICULTURAL SYSTEM
Background of the Invention
Determining an accurate route plan for an agricultural machine in an agricultural field
can enable crop material to be picked up in an efficient way, in terms of the length of time
the operation takes, and the amount of fuel used by the machine, for example. In some
applications, agricultural machines can be operated autonomously using such a route plan.
It is an object of the invention to provide a system and method for determining route-
plan-data for an agricultural vehicle or at least to provide the public or industry with a useful
choice.
Summary of the Invention
According to a first aspect of the invention, there is provided a system comprising:
a controller associated with an agricultural vehicle, the controller configured to: receive
other-vehicle-data that is representative of another vehicle that is in an agricultural field
wherein the other-vehicle-data comprises: other-vehicle-route-data that is representative of
a route to be taken by the other vehicle in the agricultural field, other-vehicle-location-data
that is representative of a location of the other vehicle in the agricultural field, other-vehicle-
speed-data that is representative of the speed of the other vehicle in the agricultural field,
receive field-data, representative of the agricultural field that has the other vehicle in it;
determine other-vehicle-dimension-data representative of the size and / or shape of the
other vehicle based on the received other-vehicle data and the received field field-data; and
determine route-plan-data that is representative of a route to be taken by the agricultural
vehicle in the agricultural field, based on the received other-vehicle-data and the determine
other-vehicle-dimension-data, wherein the controller is configured to determine the route-
plan-data such that the agricultural vehicle will avoid the other vehicle and wherein: the
agricultural vehicle has an agricultural vehicle-priority-value associated with it; and the other
vehicle has another vehicle-priority-value associated with it, and wherein the controller is
configured to: compare the agricultural vehicle-priority-value with the other-vehicle-priority-
value, and modify the earlier route plan if the agricultural vehicle-priority-value represents a
lower priority than the other-vehicle-priority-value, and the controller is configured to
determine vehicle-control-instructions for the agricultural vehicle, based on the route-plan-
data.
The other-vehicle-location-data may comprise one or more of: past-other-vehicle-
location-data, which is representative of a previous location of the other vehicle; current-
other-vehicle-location-data, which is representative of a current location of the other vehicle;
and future-other-vehicle-location-data, which is representative of a future location of the
other vehicle.
The other-vehicle-data may comprise other-vehicle-direction-data that is
representative of a direction of travel of the other vehicle.
The controller may be further configured to: receive field-data that is representative
of crop material that is to be picked up from the agricultural field by the agricultural vehicle;
and determine the route-plan-data also based on the field-data.
The controller may be configured to receive updated field-data as the agricultural
vehicle picks up the crop material from the agricultural field.
The controller may be configured to determine the route-plan-data by modifying an
earlier route plan whilst the agricultural vehicle is in use in the agricultural field.
The controller may be configured to determine vehicle-control-instructions for the
agricultural vehicle, based on the route-plan-data.
The vehicle-control-instructions may comprise vehicle-steering-instructions for
automatically controlling the direction of travel of the agricultural vehicle.
The vehicle-control-instructions may further comprise route-speed-instructions for
automatically controlling the speed of the agricultural vehicle at locations along the route.
The route-plan-data may be representative of a route to be taken by the agricultural
vehicle for an entire unprocessed portion of the agricultural field.
The system may further comprise an agricultural vehicle that is configured to be
operated in accordance with the vehicle-control-instructions. The agricultural vehicle may
be a baler.
There may be provided a computer program, which when run on a computer, causes
the computer to configure any apparatus, including a controller, processor, machine, vehicle
or device disclosed herein or perform any method disclosed herein. The computer program
may be a software implementation, and the computer may be considered as any
appropriate hardware, including a digital signal processor, a microcontroller, and an
implementation in read only memory (ROM), erasable programmable read only memory
(EPROM) or electronically erasable programmable read only memory (EEPROM), as non-
limiting examples.
The computer program may be provided on a computer readable medium, which
may be a physical computer readable medium such as a disc or a memory device, or may
be embodied as a transient signal. Such a transient signal may be a network download,
including an internet download.
Brief Description of the Drawings
Embodiments of the present invention will now be described by way of example and
with reference to the accompanying drawings in which:
Figure 1 shows an example of an agricultural field;
Figure 2 shows schematically a system that is associated with determining a route
for an agricultural vehicle to follow in an agricultural field;
Figure 3 shows schematically another system that is associated with determining a
route that a baler can follow in an agricultural field; and
Figure 4 shows schematically a further system that is associated with determining a
route for a baler to follow in an agricultural field.
Detailed Description of the Drawings
Figure 2 shows schematically a system that is associated with determining a route
for an agricultural vehicle to follow in an agricultural field 102, as shown in Figure 1. In this
example, the agricultural vehicle is a baler 100. The system includes a controller 104 that
is associated with the baler 100. It will be appreciated that the controller 104 can be located
on the baler 100, or remotely from the baler 100. For example, the functionality of the
controller 104 can be performed on a remote server, such as one “in the cloud”.
The field 102 includes rows of crop material, which may be hay, straw or similar
products that have been left in the field 102 in the form of swaths 106. The swaths 106 are
elongate rows of the products in question that are heaped in the transverse centre and tend
to flatten at the respective transverse edges. Typically a field 102 that has undergone
harvesting contains many, essentially mutually parallel, swaths 106, as shown in Figure 1.
The swaths are spaced from one another by largely consistent gaps. The crop material in
the swaths 106 can be picked up by the baler 100, and then deposited in the field 102 as
bales 108. The field 102 that is shown in Figure 1 has been partly processed, in that it
includes both rows of swath 106 for baling, and also completed bales 108.
It will be appreciated that more than one agricultural machine may be working in the
field 102 simultaneously. For example: a plurality of balers may be operational in the field
102 at the same time; or a tractor with a trailer for collecting the bales 108 may be in the
field 102 at the same time as the baler 100. One or more of the controllers 104 disclosed
herein can determine a route for an agricultural machine (such as the baler 100 of Figure
1) that takes into account information about another vehicle 107 that is in the field 102. This
can reduce the likelihood of the agricultural machine colliding with the other vehicle 107.
Controllers disclosed herein can also be used with agricultural machines that are
not balers. For example, the agricultural machine may be a tractor, a forage harvester a
combine harvester or a telehandler for gathering bales, and the controller 104 can plan a
route for the agricultural machine such that it takes into account information about any other
vehicle 107 that is in the field 102, or will be in the field 102, at the same time as the
agricultural machine.
In some embodiments, a controller (which may or not be the controller 104
associated with the baler 100 as it is shown in Figure 2) can be used to determine initial
route-plan-data 112 based on other-vehicle-data 110 that is representative of another
vehicle 107 that will be in the agricultural field 102 at the same time as the baler 110. In
this way, the route-plan-data 112 can be determined before the baler 100 and / or the other
vehicle 107 enters the field 102.
Optionally, at least the baler 100 and the other vehicle 107 may have priority-values
associated with them so that a hierarchy can be used when determining route-plans for the
vehicles. In one example, swath-data is available for the field 102 in advance of the baling
operation (for example as acquired by a drone, as will be discussed below). Then, a
controller 104 associated with the ‘master’ machine (the vehicle that has the highest priority)
can determine route-plan-data for all machines / vehicles in advance of them beginning
operation in the field 102. If complete swath-data is not available, then in some examples
the controller can use information representative of the locations of the ends of the swath
106, and then predict swath-location-data representative of the locations of the swath. In
some examples, the locations of the swath ends can be detected during baling of the
headland. It will be appreciated that any field-data, which is representative of an agricultural
field that is to be processed by the baler 100 (or any other agricultural vehicle), can be used
by the controller 104 to determine route-plan-data for a plurality of agricultural vehicles,
optionally also using priority-values associated with each of the agricultural vehicles.
Such initial planning can be performed by a controller associated with a ‘master’
machine, or a supervising controller that can be located in the cloud or can be associated
with a drone, as non-limiting examples.
The controller 104 can optionally, when performing such an initial planning phase,
use user-preference-data for determining the route-plan-data. In some examples, the
controller 104 can use user-preference-data that are associated with the ‘master’ machine
/ vehicle.
In some embodiments, the controller 104 associated with the baler 100 receives
other-vehicle-data 110 that is representative of another vehicle 107 that is in the agricultural
field 102, and determines route-plan-data 112.
As will be discussed in more detail below, the other-vehicle-data 110 can include
one or more of: other-vehicle-route-data, other-vehicle-dimension-data, other-vehicle-
location-data, other-vehicle-speed-data, and other-vehicle-direction-data. The route-plan-
data 112 is representative of a route to be taken by the baler 100 in the agricultural field,
based on the other-vehicle-data 110. As will be discussed in detail below, such processing
can enable a route plan for the baler 100 to be adapted in real-time, whilst the baler 100 is
in the field 102, to avoid the other vehicle 107.
In some examples the controller 104 can determine the route-plan-data 112 by
modifying an earlier route plan whilst the baler 100 is in use in the field 102. For instance,
an initial route plan can be generated for the baler 100 to pick up the swaths 106 of crop
material. However, when that initial route plan is generated, it may not be possible to
accurately determine where other vehicles 107 are going to be whilst the baler 100 follows
the initial route.
The route-plan-data 112 can comprise a sequence of locations for the baler 100 to
pass when picking up the crop material in the swaths 106. For example, the controller 104
can determine a shortest possible route for picking up all of the crop material, whilst avoiding
the other vehicle 107 in the field 102.
In examples where the baler 100 is pulled by a tractor, the route-plan-data 112 can
include baler-route-plan-data and tractor-route-plan-data. In this way, the controller 104
can ensure that both the baler 100 and the tractor avoid the other vehicle 107. It may only
be necessary to provide the tractor-route-plan-data as an output because it is this data that
can be used by an operator to drive the tractor such that the baler 100 follows the desired
route. Alternatively, the tractor can be controlled autonomously using the tractor-route-plan-
data, such that the baler 100 follows the desired route. It will be appreciated that any
description in this document of controlling the baler 100, can equally apply to controlling a
tractor that is pulling the baler 100 (or controlling any other agricultural machine). This is
because any such control of the tractor can be considered as indirectly controlling the baler
100.
The route-plan-data 112 can be representative of a route to be taken by the baler
100 / tractor for an entire unprocessed / un-baled portion of the field 102. That is, the route-
plan-data 112 can be determined such that it takes into account the portions of the field 102
that have already been baled, whilst ensuring that a route is planned for baling the crop
material in each of the remaining swaths 106.
In some examples, the controller 104 can determine the route-plan-data such that
the baler 100 will avoid the other vehicle 107.
The other-vehicle-data 110 can be received from the other vehicle 107 in the
agricultural field, or from any processor associated with the other vehicle 107. For example,
a remote processor that autonomously controls the other vehicle 107. In some examples,
inter-vehicle communication can be used to transfer data between the baler 100 and the
other vehicle 107. This communication can be direct or through “the cloud”.
The other-vehicle-data can include other-vehicle-route-data that is representative of
a route to be taken by the other vehicle 107. This may be an initial route that was planned
for the other vehicle 107, or may be a dynamically modified route for the other vehicle 107.
In this way, relatively long term predictions and planning can be performed, for example to
cover the duration of the agricultural operation (which could be baling). This can result in
improved / optimal routes for one or both of the baler 100 and the other vehicle 107.
In some applications, at least the baler 100 and the other vehicle 107 may have
priority-values associated with them so that a hierarchy can be used when determining /
modifying route-plans for the vehicles. For example, the controller 104 can compare a
baler-priority-value with an other-vehicle-priority-value, and only modify an earlier route plan
for the baler 100 if the baler-priority-value represents a lower priority than the other-vehicle-
priority-value. If the baler-priority-value represents a higher priority than the other-vehicle-
priority-value, then the controller 104 may not modify an existing route plan for the baler
100, on the basis that the route plan for the other vehicle 107 is expected to be changed
instead. In examples where the other vehicle 107 is also a baler, functionality described
herein can enable efficient routes to be generated such that multiple balers can operate
simultaneously in the field 102.
In some examples, the other-vehicle-data 110 includes other-vehicle-location-data
that is representative of a location of the other vehicle 107. The other-vehicle-location-data
can include one or more of: (i) past-other-vehicle-location-data, which is representative of
a previous location of the other vehicle 107; (ii) current-other-vehicle-location-data, which
is representative of a current location of the other vehicle 107; and (iii) future-other-vehicle-
location-data, which is representative of an expected future location of the other vehicle
107. The controller 104 can optionally determine such other-vehicle-location-data by
processing other-vehicle-route-plan-data that is representative of a route that is to be taken,
or is being taken, by the other vehicle 107 in the field 102. In some examples, the other-
vehicle-location-data, especially the past-other-vehicle-location-data and / or the current-
other-vehicle-location-data, may be provided by a location-determining-system (such as a
GPS receiver) associated with the other vehicle 107.
The controller 104 may process other-vehicle-route-start-time data, which is
representative of the start time of the other vehicle 107 following its current route, in order
to determine the current-other-vehicle-location-data and / or the future-other-vehicle-
location-data. In this way, other-vehicle-time-stamps can be associated with the current-
other-vehicle-location-data, and / or with specific locations that are represented by the
future-other-vehicle-location-data.
The controller 104 can then determine the route-plan-data 112 based on the other-
vehicle-location-data. For example, the controller 104 can determine a sequence of
locations that the baler 100 will occupy in the future, and associated agricultural-vehicle-
time-stamp values, as it follows a current route-plan. The controller 104 can then compare
this information with the other-vehicle-time-stamps that are associated with the future-other-
vehicle-location-data. If the controller 104 determines that the difference between the
locations of the baler 100 and the other vehicle 107 is less than a threshold-difference at
any future instant in time, then the controller 104 may determine new route-plan-data by
modifying the current / earlier route plan, such that when the baler 100 follows the new
route-plan, the difference between the locations of the baler 100 and the other vehicle 107
will not be less than a threshold-difference at any future instant in time. For instance, the
controller 104 may determine new route-plan-data by modifying the earlier route-plan such
that baler 100 slows down whilst following the same trajectory as that of the earlier route-
plan.
In some examples, the other-vehicle-data comprises other-vehicle-speed-data that
is representative of the speed of the other vehicle 107. The other-vehicle-speed-data can
include one or more of: (i) past-other-vehicle-speed-data, which is representative of a
previous speed of the other vehicle 107; (ii) current-other-vehicle-speed-data, which is
representative of a current speed of the other vehicle 107; and (iii) future-other-vehicle-
speed-data, which is representative of an expected future speed of the other vehicle 107.
The controller 104 can optionally determine such other-vehicle-speed-data by processing
other-vehicle-route-plan-data that is representative of a route that is to be taken, or is being
taken, by the other vehicle 107 in the field 102, and the speed that the other vehicle 107 is
intended to have at various points along the route. The controller 104 may also process
other-vehicle-route-start-time data in order to determine the current-other-vehicle-speed-
data and / or the future-other-vehicle-speed-data at various points in time in the future. In
some examples, the other-vehicle-speed-data, especially the past-other-vehicle-speed-
data and / or the current-other-vehicle-speed-data, may be provided by a speedometer or
a location-determining-system associated with the other vehicle 107.
Optionally, the controller 104 may process the past-other-vehicle-speed-data and
the current-other-vehicle-speed-data in order to make a statistical prediction of the future-
other-vehicle-speed-data. For instance, if the other vehicle 107 has been travelling at the
same speed for a threshold-period of time, then the controller 104 may predict that the other
vehicle 107 will continue to travel at that speed, and therefore attribute a historical speed
value for the future-other-vehicle-speed-data.
The controller 104 can process the other-vehicle-speed-data in order to determine
the future-other-vehicle-location-data. Therefore, the controller 104 can determine the
route-plan-data 112 based on, directly or indirectly, the other-vehicle-speed-data.
In some examples, the other-vehicle-data comprises other-vehicle-direction-data
that is representative of the direction of travel of the other vehicle 107. The other-vehicle-
direction-data can include one or more of: (i) past-other-vehicle-direction-data, which is
representative of a previous direction of the other vehicle 107; (ii) current-other-vehicle-
direction-data, which is representative of a current direction of the other vehicle 107; and
(iii) future-other-vehicle-direction-data, which is representative of an expected future
direction of the other vehicle 107. The controller 104 can optionally determine such other-
vehicle-direction-data by processing other-vehicle-route-plan-data that is representative of
a route that is to be taken, or is being taken, by the other vehicle 107 in the field 102, and
the direction that the other vehicle 107 is intended to have at various points along the route.
The controller 104 may also process other-vehicle-route-start-time data in order to
determine the current-other-vehicle-direction-data and / or the future-other-vehicle-
direction-data at various points in time in the future. In some examples, the other-vehicle-
direction-data, especially the past-other-vehicle-direction-data and / or the current-other-
vehicle-direction-data may be provided by a gyroscope or a location-determining-system
associated with the other vehicle 107.
Optionally, the controller 104 may process the past-other-vehicle-direction-data and
the current-other-vehicle-direction-data in order to make a statistical prediction of the future-
other-vehicle-direction-data. For instance, if the other vehicle 107 has been travelling in the
same direction for a threshold-period of time, then the controller 104 may predict that the
other vehicle 107 will continue to travel in that direction, and therefore attribute a historical
direction value for the future-other-vehicle-direction-data.
The controller 104 can process the other-vehicle-direction-data in order to determine
the future-other-vehicle-location-data. Therefore, the controller 104 can determine the
route-plan-data 112 based on, directly or indirectly, the other-vehicle-direction-data.
In some examples, the other-vehicle-data comprises other-vehicle-dimension-data
that is representative of the size and / or shape of the other vehicle. The other-vehicle-
dimension-data may be fixed / hard-coded for a specific type of other vehicle 107, or it may
be determined using one or more sensors. In such examples, the controller 104 can
determine the other-vehicle-location-data as a multiple set of coordinates for the other
vehicle 107. The multiple set of coordinates may be representative of the locations of one
or more corners of the other vehicle 107, for example, and may be sufficient such that,
together, they can be used to determine the perimeter of a two-dimensional footprint of the
other vehicle 107 (when viewed from above), or to determine the perimeter of the three-
dimensional volume of the other vehicle 107.
The controller 104 can determine the multiple sets of coordinates by applying offsets
to the location of the other vehicle 107 (other-vehicle-location-data) at any point along a
route that is to be followed by the other vehicle 107. The controller 104 can determine the
offsets based on the other-vehicle-dimension-data.
The controller 104 can then determine the route-plan-data 112 based on the other-
vehicle-dimension-data, optionally in combination with the other-vehicle-location-data.
Therefore, the other-vehicle-data can include data relating to one or more of the
other vehicle’s location, dimensions, groundspeed and planned route (desired trajectory) if
available. In some examples, the other-vehicle-data 110 can be determined from sensor
data that is acquired from a sensor that monitors the other vehicle 107. For instance, an
unmanned aerial vehicle can acquire image data using a camera in order for the movement
of the other vehicle 107 to be monitored.
Figure 3 shows schematically another system that is associated with determining a
route that a baler 200 can follow in an agricultural field (as shown in Figure 1). The system
includes a controller 204 and the baler 200. The controller 204 can be used to
autonomously control the baler 200 (or a tractor that pulls the baler 200). That is, the system
can be considered as including the baler 200 that is configured to be operated in accordance
with vehicle-control-instructions.
In this example the controller 204 receives other-vehicle-data 210 and field-data
216, and determines the route-plan-data 212 based on the other-vehicle-data 210 and the
field-data 216 as will be described below.
The controller 204 determines vehicle-control-instructions 218 for the baler 200,
based on the route-plan-data 212. The vehicle-control-instructions 218 can comprise
vehicle-steering-instructions for automatically controlling the direction of travel of the baler
200, such that the baler 200 follows a specific route through the agricultural field. In this
way, the baler 200 can be autonomously controlled such that it follows a specific route
through the agricultural field in order to pick up crop material from the field. In addition to,
or instead of, avoiding an other vehicle that is in the field, as discussed above, the route
can be planned such that it provides one or more advantages, for example:
(i) efficient baler / tractor usage, such as low overall fuel consumption to pick up and
bale all of the crop material from the field;
(ii) efficient baling in terms of the time required to bale all of the crop material in the
field; and
(iii) prioritising pick up of crop material with particular characteristics (as defined by
crop-property-data for example, as will be discussed below), such as portions of swath that
have a high volume of crop material.
In some examples, the controller 204 can also use baler-location data and / or baler-
direction-data, that is representative of a current location and direction of travel of the baler
200 for which the route plan is being determined, to determine the route-plan-data 212.
The vehicle-control-instructions can also comprise route-speed-instructions for
automatically controlling the speed of the baler 200 at locations along the route. For
instance, the vehicle-control-instructions can also comprise vehicle-steering-instructions
and route-speed-instructions such that the baler 200 can make a turn in the field with a
desired turning angle, at an appropriate speed for the turn, such that the baler 200 avoids
another vehicle that is in the field.
As indicated above, in this example, the controller 204 also receives field-data 216,
which is representative of an agricultural field that is to be processed by the baler 200. For
example, the field-data 216 is representative of the swaths of crop material that are to be
picked up from the field by the baler. In one instance, the field-data 216 can be
representative of the location of the swaths of crop material that are still to be baled. The
field-data 216 can also be representative of one or more properties of the swaths of crop
material. In some examples, the controller 204 receives updated field-data 216 as the baler
200 picks up the crop material from the field.
The controller 204 can determine the route-plan-data 212 also based on the field-
data 216. In this way, both the locations of one or more other vehicles, and properties of
the un-baled swaths (such as the locations of the swaths), can be used to determine the
route-plan-data 212. In other examples, the field-data 216 can be used to determine the
other-vehicle-data 210, as will be discussed detail below with reference to Figure 4.
In some examples, any controller disclosed herein can determine route-plan-data
such that an agricultural vehicle takes a path that has a predetermined relationship with a
route of the other vehicle. In one example, the controller can determine the route-plan-data
such that the agricultural vehicle follows a path (at least for a threshold distance / time) that
is parallel with, and spaced apart by a predetermined distance from, a path that is to be
followed by the other vehicle. For example, the route can be planned so that material or
fuel can be transferred between the agricultural vehicle and the other vehicle. Such
examples can be particularly relevant for combine and forage harvesters, or any other
agricultural vehicle that transfers crop material between vehicles, including containers that
are towed by vehicles. In one specific example, a first combine harvester can unload into
a second combine harvester next to it, and the second combine harvester then unloads into
a truck. Such examples can benefit from route-plan-data being determined for two or more
of the vehicles, such that it that takes into account other-vehicle-data.
A possible control strategy could be to divide the field into zones, then then dedicate
different zones to different machines. Another strategy could be to keep the machines close
to each other, for example in big fields it may be disadvantageous for a plurality of machines
/ vehicles to be long distances away from each other. Therefore, route-plan-data can be
determined for a plurality of agricultural vehicles such that a distance between their
instantaneous locations whilst following the routes is less than a threshold-distance. In this
way, a vehicle can be said to take a path that has a predetermined relationship with a route
of the other vehicle.
Figure 4 shows schematically a further system that is associated with determining a
route for a baler 300 to follow in an agricultural field 302. Features of Figure 4 that are also
shown in Figure 2 or Figure 3 have been given corresponding reference numbers in the 300
series, and will not necessarily be described again here.
The system includes a vehicle 320. In this example the vehicle is an unmanned
vehicle 320. The unmanned vehicle 320 can be an unmanned aerial vehicle (sometimes
referred to as a drone). In other examples, the vehicle 320 could be a land vehicle, which
may or may not be unmanned.
The unmanned vehicle 320 can include one or more sensors for obtaining field-data
316. A field of view 326 of such a sensor is shown schematically in Figure 4.
In this example, the unmanned vehicle 320 includes a sensor 322 that can acquire
field-data 316. In this example the sensor 322 is a camera that can acquire field-image-
data. The field-image-data can be two-dimensional-image-data or three-dimensional-
image-data, and in some examples the camera can be a 3D-scanner or 3D-camera.
Alternatively, or additionally, the field-data 316 can include: field-radar-data acquired
by a radar, field-LIDAR-data acquired by a LIDAR sensor; field-moisture-data acquired by
a moisture-sensor, field-IR-data acquired by an infra-red-sensor, ultrasonic-data acquired
by an ultrasonic sensor, or any other type of field-data from any type of sensor that can
acquire information about the agricultural field 302 or the crop material in the agricultural
field 302. The controller 304 can process one or more of these different types of field-data
316, either directly or indirectly, in order to determine the route-plan-data 312, and optionally
vehicle-control-instructions (not shown).
In some examples, the controller 304 can determine crop-property-data that is
representative of the crop material in the agricultural field 302, based (directly or indirectly)
on the field-data 316. For instance, the controller 304 can perform an object recognition
algorithm on the field-image-data in order to determine one or more of crop-type; length of
stalks in the material, material density, and stub-height-information. The stub height is the
height at which the crop is cut off. In some conditions, such as for wheat straw, the swath
lays on top of the stubs, which causes the swath to look bigger than it actually is.
In some examples, the controller 304 can also, or instead, process different types
of field-data to determine the crop-property-data. For instance, the controller 304 can
process field-IR-data to determine the temperature of crop material, or the controller 304
can process field-moisture-data to determine the humidity / wetness of crop material.
In one example, the crop-property-data can include material-size-data that is
representative of the size of the crop material in the agricultural field 302. Such material-
size-data can include the height, width, cross-sectional area, volume, or shape of the swath
306. The crop-property-data can therefore represent one-dimensional, two-dimensional or
three-dimensional physical characteristics of the crop material, and can be determined
based on two-dimensional-image-data or three-dimensional-image-data.
The controller 304 can then determine the route-plan-data 312 for the baler 300
based on one or more of the above types of crop-property-data. In some examples, the
controller 304 determines vehicle-control-instructions for the baler 300 based on one or
more of the above types of crop-property-data. For example, the controller 304 may
cause the baler 300 to travel: (i) more slowly over large portions of crop material (for
instance portions that have a material-size-data (such as cross-sectional area) that is
greater than a size-threshold-value); (ii) more quickly over thin portions of crop material (for
instance portions that have a density that is less than a density-threshold-value), (iii) in a
zig-zag path over very narrow swaths to get a good feeding of a pre-compression chamber
of the baler 300; and (iv) not changing the speed too aggressively (for example such that
the acceleration / deceleration of the baler 300 is not greater than a speed-change-
threshold) if there is a small interruption of the swath 306 to improve driver comfort (for
example, a small interruption can be identified as a height of the swath 306 that is less than
a swath-height-threshold for a length of the path that is less than a path-length-threshold).
It will be appreciated that the above examples are non-limiting and that the baler
can be automatically controlled based on crop-property-data in numerous other ways. In
some examples, different options can be selected by the operator of the baler / tractor, such
as when starting a baling operation. For instance, when starting a field, the operator may
be able to enter a ‘setting’ such as the following:
-If I hit a wet spot: how should the controller control the baler / tractor - slow down
the speed and continue baling or lift the pick-up; and / or
-If a highly compressed swath is detected: how should the controller control the baler
/ tractor - slow down the speed and continue baling or lift the pick-up.
In this way, the controller can determine vehicle-control-instructions for the baler 300
based on: (i) one or more of the above types of crop-property-data; and (ii) user input.
Therefore, in a number of ways, the controller 304 can determine vehicle-control-
instructions and / or route-plan-data 312 based on the crop-property-data. For instance,
the controller 304 may plan the route for the baler 300 such that regions of the crop material
with a higher density are picked up before regions of the crop material that have a lower
density. This may be advantageous so that the most valuable crop material (in terms of
volume of crop per distance travelled by the baler 300) is picked up first. In another
example, the controller 304 may plan the route such that the baler 300 picks up regions of
the crop material that have a lower humidity before regions of the crop material that have a
higher humidity. In this way, the more humid crop material will have longer to dry out. As
a further example, the controller 304 can determine the route-plan-data 312 for the baler
300 based on the time of day that the crop material is to be picked up and / or a measured
or predicted temperature of the crop material. It can be advantageous for the crop material
to be as cool as possible for baling (for better friction properties). Therefore, the route-plan-
data 312 can be planned such that the crop material that is picked up is likely to be below
a crop-temperature-threshold. As yet further example, the controller 304 can determine the
route-plan-data for the baler 300 based on the humidity / wetness of crop material such that
wet spots of the crop material can be baled after each other so as not to mix wet and dry
crop in the same bales.
The controller 304 can determine field-property-data that is representative of a
property of the agricultural field 302, based on the field-data 316. For instance, the
controller 304 can determine first regions of field-data that correspond to the swaths 306 of
crop material, and second regions of the field-data that correspond to the agricultural field
302 (outside the perimeter of the first regions of field-data). As discussed above, the
controller 304 can determine crop-property-data based on data that corresponds to the first
regions of field-data. The controller 304 can also determine field-property-data based on
the second regions, and then determine the vehicle-control-instructions and / or route-plan-
data 312 based on the field-property-data.
The field-property-data can include field-wetness-data that is representative of the
wetness of the agricultural field 302. In such an example, the controller 304 can process
field-data to identify the locations of the second regions of the field-data that correspond to
the agricultural field 302, and then determine the field-wetness-data based on field-
moisture-data acquired by a moisture-sensor for the identified second regions. The
controller 304 can then control the speed of the baler 300 accordingly, for example to
prevent the baler 300 from travelling faster than a speed-threshold-value in parts of the field
302 that have a field-wetness-data that exceeds a wetness-threshold-value.
The field-property-data can also include field-contour-data that is representative of
contours of the agricultural field 302. A user can provide the field-contour-data to the
controller 304 in some examples because this data acquisition can be considered as a one-
time job. In other examples, the controller 304 can determine the field-contour-data based
on the field-image-data or field-radar-data, for example. The controller 304 can then
determine the vehicle-control-instructions and / or route-plan-data 312 based on the field-
contour-data. For instance, for regions of the agricultural field 302 that have a steep slope
(for example, field-contour-data that is representative of a gradient that is greater than a
gradient-threshold-value), the controller 304 may determine route-speed-instructions for
automatically controlling the speed of the baler 300 such that it does not exceed a speed-
threshold-value. Also, in such circumstances, the controller 304 may determine vehicle-
steering-instructions that prevent a steering angle of the baler 300 from exceeding a
steering-angle-threshold-value. As another example, the controller 304 can determine the
route-plan-data for the baler 300 based on the field-contour-data. For example, the
controller 304 can calculate a route that, for a big swath on a flank, results in the baler 300
picking up the crop material as it is travelling down a slope that has a gradient that is greater
than a gradient-threshold-value. This can provide advantages because in some
applications, a tractor that is pulling baler 300 may not have sufficient power to maintain its
optimal speed.
In some examples, the vehicle 320 can include a height-measurement-sensor for
acquiring material-height-data representative of the height of the crop material. The
controller 304 can then determine the vehicle-control-instructions and / or route-plan-data
312 based on the material-height-data. For instance, the controller 304 may set the route-
speed-instructions for the baler 300 based on the material-height-data, such that the baler
300 travels more slowly when the height of the crop material is relatively large. The height
measurement can be used as an indicator of the size of the swath 306. If multiple height
measurements are taken whilst the vehicle 320 is moving, they can be combined in order
to provide a 3D-scan. The height-measurement-sensor can also be used to measure stub-
height-information, which is representative of stub height, if the stub density is high enough.
Irrespective of how the stub height is determined, in some examples the controller 304 can
subtract the stub height from the measured height of the crop in order to determine swath-
height-data. The controller 304 can then determine the vehicle-control-instructions and / or
route-plan-data 312 based on the swath-height-data.
In some examples, the controller 304 can determine a bale-count, representative of
an estimate of the number of bales that will be attained by picking up all of the crop material,
based on the field-data 316. For instance, the controller 304 can process material-size-
data (representative of the size of the crop material), and calculate total-crop-amount that
is representative of the total amount of crop that is to be picked up. The controller 304 can
then divide the total-crop-amount by the volume of a single bale to determine the bale-
count. Providing the bale-count as an output can be useful for planning the operation of
picking up the crop material. For instance, the number of trucks that will be needed to
collect the bales 308, and how long the job will take, can be estimated in advance. This
type of information can be particularly advantageous inputs for work planning. For instance,
the controller 304 can process the total-crop-volume and / or bale-count in order to
determine energy requirements of the baler 300. For example, if the total-crop-volume is
very large, then the controller 304 can determine that the baler 300 will have to return at
some point to a location where it can refill with more energy / fuel. Therefore, the controller
304 can determine a route that takes this into account, and / or can automatically control
the baler 300 such that its available energy / fuel is used in an appropriate way for the
required future refill of energy / fuel. The controller 304 can determine both an initial bale-
count and / or energy requirements prior to the operation of picking up the crop material,
and an updated bale-count and energy requirements during the operation.
The vehicle 320 can acquire: (i) field-data 316 that is representative of the
agricultural field 302 that has the other vehicle 307 located in it; and (ii) field-location-data
(not shown) associated with the field-data 316. The controller 304 can optionally determine
the route-plan-data 312 based on the field-data 316 and the field-location-data.
In this example, the vehicle 320 acquires field-location-data associated with field-
image-data. For example, the vehicle 320 may have a location-determining-system 324,
such as GPS, that provides vehicle-location-data that is representative of the location of the
vehicle 320 when the field-image-data is acquired. The controller 304 may also receive
camera-direction-data and vehicle-altitude-data. The camera-direction-data may be
representative of the direction that the camera is facing relative to the vehicle 320. The
camera-direction-data may be hard coded if the camera is non-movably fixed to the vehicle
320. If the camera is movably mounted to the vehicle 320, then the camera-direction-data
can take different values, which may be received as an input-signal at the controller 304
from the vehicle 320. The controller 304 can then use a simple trigonometric algorithm to
attribute field-location-data to objects / areas that are represented by the field-image-data
based on the vehicle-location-data, the camera-direction-data, a vehicle-altitude-data (if the
vehicle 320 is an aerial vehicle), and a direction of travel of the vehicle 320, as is known in
the art.
In some examples, the controller 304 can determine the other-vehicle-data 310
based on the field-data 316 and the field-location-data. The controller 304 can determine
one or more of other-vehicle-location-data, other-vehicle-speed-data, other-vehicle-
direction-data, and other-vehicle-dimension-data based on the field-data and / or the field-
location-data. In which case, the controller 304 can determine some, or all, of the other-
vehicle-data based on the field-data 316 and the field-location-data, and the controller 304
may not need to receive the other-vehicle-data 310 separately such as directly from the
other vehicle 307.
Use of an aerial vehicle 320 can enable field-data 316 to be acquired from a
relatively high altitude to obtain an overview of the field 302, thereby providing a wide field
of view. Subsequently or alternatively, the aerial vehicle 320 can stay with the baler 300 at
a lower altitude. The gathered field-data 316 can be streamed to the controller 304 and /
or “the cloud”. When the aerial vehicle 320 stays with the baler 300, one or more of the
following strategies can be deployed. Firstly, the aerial vehicle 320 can fly above the baler
300 to get information about the surroundings of the baler 300. In this way, it can detect
objects ahead of the baler 300 and also determine one or more properties of the other
vehicle 307. Secondly, the aerial vehicle 320 can fly ahead of the baler 300 to scan the
future trajectory of the baler 300 for objects. Thirdly, the aerial vehicle 320 can scan the
whole field 302 to get an overview of any obstacles, including other vehicles 307.
It will be appreciated that one or more of the functions of the vehicle 320 that are
described with reference to Figure 4 could be implemented by the agricultural vehicle / baler
300 itself in some examples. For example, field-data and crop-property-data could be
determined by processing signals acquired by sensors on the agricultural vehicle / baler
300.
One or more of the examples disclosed herein can improve the safety with which a
baler operates because collisions with objects, such as other vehicles 307, are less likely.
Systems described herein can dynamically map and / or predict characteristics of
other vehicles in the field during baling, and can utilise technology to gather the data for
mapping the other vehicles, and can determine a route for the baler and / or automatically
control the baler. In some examples, a drone can be used for mapping the other vehicle.
Also, information about the other vehicles that is produced by the other vehicle itself, can
be used.
It will be appreciated that any of the control operations disclosed herein, such as
setting the speed or direction of travel of the baler or an associated tractor, can be
performed by comparing data with one or more threshold values, applying an algorithm to
data, or using a look-up-table / database to determine a control value based on received /
determined data.
Claims (12)
1. A system comprising: a controller associated with an agricultural vehicle, the controller configured to: 5 receive other-vehicle-data that is representative of another vehicle that is in an agricultural field wherein the other-vehicle-data comprises: other-vehicle-route-data that is representative of a route to be taken by the other vehicle in the agricultural field, other-vehicle-location-data that is representative of a location 10 of the other vehicle in the agricultural field, other-vehicle-speed-data that is representative of the speed of the other vehicle in the agricultural field, receive field-data, representative of the agricultural field that has the other vehicle in it; 15 determine other-vehicle-dimension-data representative of the size and / or shape of the other vehicle based on the received other-vehicle data and the received field field-data; and determine route-plan-data that is representative of a route to be taken by the agricultural vehicle in the agricultural field, based on the received other-vehicle-data 20 and the determine other-vehicle-dimension-data, wherein the controller is configured to determine the route-plan-data such that the agricultural vehicle will avoid the other vehicle and wherein: the agricultural vehicle has an agricultural vehicle-priority-value associated with it; and 25 the other vehicle has another vehicle-priority-value associated with it, and wherein the controller is configured to: compare the agricultural vehicle-priority-value with the other-vehicle-priority- value, and modify the earlier route plan if the agricultural vehicle-priority-value 30 represents a lower priority than the other-vehicle-priority-value, and the controller is configured to determine vehicle-control-instructions for the agricultural vehicle, based on the route-plan-data.
2. The system of claim 1, wherein the other-vehicle-location-data comprises one or more of: past-other-vehicle-location-data, which is representative of a previous location of the other vehicle; 5 current-other-vehicle-location-data, which is representative of a current location of the other vehicle; and future-other-vehicle-location-data, which is representative of a future location of the other vehicle. 10
3. The system of claim 1 or claim 2, wherein the other-vehicle-data comprises other- vehicle-direction-data that is representative of a direction of travel of the other vehicle.
4. The system of any one of claims 1 to 3, wherein the controller is further configured 15 receive field-data that is representative of crop material that is to be picked up from the agricultural field by the agricultural vehicle; and determine the route-plan-data also based on the field-data.
5. The system of claim 4, wherein the controller is configured to receive updated field- 20 data as the agricultural vehicle picks up the crop material from the agricultural field.
6. The system of any one of claims 1 to 5, wherein the controller is configured to determine the route-plan-data by modifying an earlier route plan whilst the agricultural vehicle is in use in the agricultural field.
7. The system of any one of claims 1 to 6, wherein the vehicle-control-instructions comprise vehicle-steering-instructions for automatically controlling the direction of travel of the agricultural vehicle. 30
8. The system of claim 7, wherein the vehicle-control-instructions further comprise route-speed-instructions for automatically controlling the speed of the agricultural vehicle at locations along the route.
9. The system of any one of claims 1 to 8, wherein the route-plan-data is representative 35 of a route to be taken by the agricultural vehicle for an entire unprocessed portion of the agricultural field.
10. The system of any one of claims 1 to 9, wherein the system further comprises an agricultural vehicle that is configured to be operated in accordance with the vehicle-control- instructions.
11. The system of any one of claims 1 to 10, wherein the agricultural vehicle is a baler.
12. The system of claim 1 for determining route-plan-data that is representative of a route to be taken by the agricultural vehicle in the agricultural field as hereinbefore described 10 with reference to the figures.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201910778285.4 | 2019-08-22 | ||
| CN201910778285.4A CN110518745A (en) | 2019-08-22 | 2019-08-22 | Motor radiating structure |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| NZ759207A NZ759207A (en) | 2021-05-28 |
| NZ759229B2 true NZ759229B2 (en) | 2021-08-31 |
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