This application claims priority to Japanese Patent Application No. 2016-253471 filed Dec. 27, 2016, the disclosure of which is hereby incorporated in its entirety by reference.
This invention relates to a work vehicle including an imaging device for imaging a plant growing in a field.
A work vehicle disclosed in JP 2014-042490 A includes a front camera for imaging a turf surface area present in an advancing direction. A location where turf is shaved and exposed (called a “divot” in JP 2014-042490 A) is detected from the image and a sand filling work for the divot is carried out. However, JP 2014-042490 A discloses only that a sand filling work for the divot is carried out based on result of imaging by the imaging device. There remains room for improvement for efficiently carrying out field management.
Then, there is proposed a work vehicle as under:
A work vehicle comprising:
an imaging device for imaging a plant growing in a field;
a sowing device for sowing seeds in the field; and
a control device for controlling the sowing device, the control device including:
With the above arrangement, while an imaging operation is being carried out by the imaging device, seeds can be sown at a location where the growth state of the plant is poor, whereby field management can be carried out in an efficient manner.
According to one preferred embodiment, the work vehicle further comprises: a vehicle speed sensor for detecting a vehicle speed of the work vehicle;
wherein:
the imaging device is disposed at a front portion of a vehicle body;
the sowing device is disposed at a rear portion of the vehicle body;
the control device includes an expected passage time calculation section for calculating an expected passage time when the sowing device is expected to pass over the plant imaged by the imaging device; and
the sowing instruction section instructs the sowing device to carry out the seed sowing operation when the expected passage time calculated by the expected passage time calculation section has lapsed.
With the above arrangement, a slight time lag occurs until the sowing device passes over the plant imaged by the imaging device. Then, as the sowing instruction section instructs the sowing device to carry out the seed sowing operation when the expected passage time calculated by the expected passage time calculation section has lapsed, seeds can be sown in the field in accordance with the timing of locating of the sowing device on the plant imaged by the imaging device.
According to another preferred embodiment, the control device includes a growth density calculation section for calculating growth density of the plant in the field based on the result of imaging of the imaging device; and
the growth state determination section determines the growth state of the plant in the field based on result of calculation by the growth density calculation section.
If the growth density of the plant in the field is high, it can be assumed that the growth state of the plant in the field is good. If the growth density of the plant in the field is low, it can be assumed that the growth state of the plant in the field is poor. With the above arrangement, the growth state of the plant in the field can be determined in an accurate manner.
According to still another preferred embodiment, the control device further includes:
With the above arrangement, by correlating the location information acquired by the location information acquisition section with the result of calculation by the growth density calculation section, it is possible to obtain information (e.g. a field map) useful for efficiently carrying out the field management.
According to still yet another preferred embodiment, the sowing device includes:
wherein the sowing instruction section instructs the sowing device to carry out the sowing operation in such a manner that the lower is the growth density of the plant in the field, the greater becomes the opening degree of the opening/closing member.
With the above arrangement, the lower the growth density of the plant in the field, the greater the amount of seeds to be sown in the field. Thus, the sowing operation can be carried out in an efficient manner.
According to one preferred embodiment, the work vehicle comprises a riding type lawn mower.
With the above arrangement, by carrying out a lawn mowing operation and a sowing operation as a series of operations, the work can be carried out in an efficient manner.
In the case of a riding type lawn mower, if the sowing device is disposed on more rear side than a mower device for mowing lawn in a field, seeds will be sown in the field by the sowing device after lawn in the field is mowed by the mowing device. With this, the seeds can reach the ground surface more easily than a case of sowing the seeds in the field where lawn has grown fully.
Further, when the imaging device images an area before lawn has been mowed by the mowing device, this area prior to mowing by the mowing device will show the present growth state of the lawn in the field clearly, so that the growth state of the lawn in the field can be determined accurately.
Further and other features and advantageous effects achieved thereby will become apparent upon reading the following explanation with reference to the accompanying drawings.
An exemplary embodiment of a work vehicle according to the present invention will be described next with reference to the drawings.
A sowing device 5 is provided rearwardly of the hood 4 for sowing seeds (lawn seeds) in the field. The sowing device 5 is disposed at a rear portion of the vehicle body. Namely, the sowing device 5 is on more rear side than the mower deck 2. The sowing device 5 includes a storage section 5a for storing seeds and a shutter 5b (corresponding to an “opening/closing member”) for opening/closing a feed opening (not shown) for feeding seeds inside the storage section 5a to the field.
A camera 6 (corresponding to an “imaging device”) is mounted at a front portion of the mower deck 2 for imaging lawn growing in the field. The camera 6 is disposed at a front portion of the vehicle body. The camera 6 captures images of an area before lawn is mowed by the mower deck 2.
The growth density calculation section 9 calculates a growth density (ρg) of the lawn in the field, based on the result of imaging (image) of the camera 6. The growth state determination section 10 determines a growth state of lawn in the field, based on the result of calculation (growth density ρg) of the growth density calculation section 9. Specifically, the growth state determination section 10 determines that the growth state of lawn in the field is “not good” if the growth density (ρg) is less than a reference growth density (ρs) (i.e. ρg<ρs); and determines that the growth state of lawn in the field is “good” if the growth density (ρg) is equal to or higher the reference growth density (ρs) (i.e. ρg>=ρs).
The expected passage time calculation section 11 calculates an expected passage time (Tp) when the sowing device 5 passes over the lawn imaged by the camera 6. In this case, if a distance (L) (see
The sowing instruction section 12 instructs the sowing device 5 to carry out a sowing operation, based on the result of determination by the growth state determination section 10. In this, the sowing instruction section 13 instructs the sowing device 5 to carry out the sowing operation, such that the lower is the growth density (μg), the greater becomes the opening degree of the shutter 5b. More particularly, the sowing instruction section 12 switches the opening degree of the shutter 5b in three stages (closed stage, small opening stage and large opening stage) in accordance with the growth density (μg). Also, the sowing instruction section 12 instructs the sowing device 5 to carry out the sowing operation upon lapse of the expected passage time (Tp), such that the sowing device 5 sows seeds in the field in accordance with the timing at which the sowing device 5 is located on the lawn imaged by the camera 6.
The location information acquisition section 13 acquires location information (I1) of the vehicle body by receiving radio wave from a global positioning system (GPS) 14. The correlation section 15 correlates the vehicle body location information (I1) acquired by the location information acquisition section 13 with the growth density (ρg).
The communication section 16 effects communication with a server 18 via a mobile terminal 17 (e.g. a smartphone, a tablet, etc.) carried by the operator (or not via the mobile terminal 17). The information correlated by the correlation section 15 (position information I1 multiplied by growth density ρg) (i.e. I1*ρg)) is transmitted from the communication section 16 to the server 18. In the server 18, a field map M related to the position information (I1) and the growth density (ρg) is produced. As the communication section 16 receives the field map P from the server 18, the field map M can be utilized for field management.
As shown in
At step S2, the growth state determination section 10 determines that the growth state of lawn in the field is “good” if the growth density (ρg) is equal to or higher than the reference growth density (ρs) (i.e. ρg>=ρs) (step S2: No). In this case, the shutter 5b will be maintained under a closed state (step S3).
On the other hand, at step S2, the growth state determination section 10 determines that the growth state of lawn in the field is “not good” if the growth density (ρg) is less than the reference growth density ρs (i.e. ρg<ρs) (step S2: Yes).
Then, at step S4, if the growth density (ρg) is 0 (zero) (ρg=0) (step S4: Yes), the sowing instruction section 12 instructs the sowing device 5 to carry out a sowing operation when an expected passage time (Tp) has lapsed (step S5: Yes). With this, the shutter 5b is switched to the opened state (the large opening stage) by the driving section 8 (step S6).
On the other hand, at step S4, if the growth density (ρg) is not 0 (zero) (0<ρg<ρs) (step S4: No), the sowing instruction section 12 instructs the sowing device 5 to carry out a sowing operation when an expected passage time (Tp) has lapsed (step S7: Yes). With this, the shutter 5b is switched to the opened state (the small opening stage) by the driving section 8 (step S8).
(1) In the foregoing embodiment, the growth state determination section 10 determines a growth state of lawn in the field, based on the growth density (ρg). Instead thereof, the growth state determination section 10 can determine the growth state of the lawn in the field, based on a factor other than growth density (ρg) (e.g. color of the lawn, etc.).
(2) In the foregoing embodiment, the sowing instruction section 12 switches the opening degree of the shutter 5b in three stages (closed stage, small opening stage and large opening stage) in accordance with the growth density (ρg). Instead thereof, the sowing instruction section 12 can switch the opening degree of the shutter 5b in four or more stages in accordance with the growth density (ρg). Or, the sowing instruction section 12 can switch the opening degree of the shutter 5b in two stages (closed stage and opened stage).
(3) In the foregoing embodiment, lawn is assumed as a “plant” related to the invention. However, the “plant” related to the invention is not limited to lawn.
(4) The present invention is applicable not only to the riding type lawn mower as one illustrated in the foregoing embodiment, but also to a work vehicle not having a mowing device.
Number | Date | Country | Kind |
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2016-253471 | Dec 2016 | JP | national |
Number | Date | Country |
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2000245215 | Sep 2000 | JP |
2003250318 | Sep 2003 | JP |
2012198688 | Oct 2012 | JP |
2014042490 | Mar 2014 | JP |
201523819 | Feb 2015 | JP |
2016202061 | Dec 2016 | JP |
101406210 | Jun 2014 | KR |
Entry |
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KR101406210, Machine Translation (Year: 2014). |
JP-2012198688-A—Machine Translation (Year: 2012). |
“The lawn in the vestibular, further chase”, 2009, https://yaplog.jp/unterrichten/archive/329 (downloaded from the internet Oct. 16, 2019). |
Number | Date | Country | |
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20180177123 A1 | Jun 2018 | US |