Source: https://patents.google.com/patent/JP2009519393A/en
Timestamp: 2020-01-23 15:07:35
Document Index: 614071150

Matched Legal Cases: ['Application No. 60', 'art 28', 'art 60', 'art 16', 'art 90', 'art 90']

JP2009519393A - Small machine tool transporter with articulated nodes - Google Patents
Small machine tool transporter with articulated nodes Download PDF
JP2009519393A
JP2009519393A JP2008545807A JP2008545807A JP2009519393A JP 2009519393 A JP2009519393 A JP 2009519393A JP 2008545807 A JP2008545807 A JP 2008545807A JP 2008545807 A JP2008545807 A JP 2008545807A JP 2009519393 A JP2009519393 A JP 2009519393A
JP2008545807A
コディー エル ソーウェル
ザ チャールズ マシン ワークス インコーポレイテッド
2005-12-13 Priority to US75041905P priority Critical
2006-12-13 Application filed by ザ チャールズ マシン ワークス インコーポレイテッド filed Critical ザ チャールズ マシン ワークス インコーポレイテッド
2006-12-13 Priority to PCT/US2006/047709 priority patent/WO2007070638A2/en
2009-05-14 Publication of JP2009519393A publication Critical patent/JP2009519393A/en
It is intended to provide an upright riding construction vehicle with a configuration suitable for many applications. The upright riding construction vehicle includes a base unit, a connection node, and one type of a plurality of replaceable instrument chassis. The base unit includes at least one ground support member and provides power and mobility to the construction vehicle. The articulation node is supported at the front end of the base unit. The operator station overhangs from the rear end of the base unit. Each of the plurality of chassis has at least one ground support member and is pivotally connected to the base unit by a connection node. Each of the plurality of chassis may be a dedicated instrument chassis or a general-purpose instrument chassis. Each dedicated chassis is equipped with a dedicated tool. Each general-purpose chassis includes an attachment surface for connecting to one of a plurality of tools. The ground support member may be any of various combinations such as a drive wheel, a follower wheel, a caterpillar, and a tool.
This application claims priority from US Provisional Application No. 60 / 750,419, filed December 13, 2005, the contents of which are incorporated herein by reference in their entirety. Shall.
The present invention relates to the field of outdoor equipment, and in particular, relates to upright built-up building equipment.
One aspect of the present invention is directed to a construction vehicle.
Another aspect of the present invention is directed to an articulated construction vehicle.
Another aspect of the present invention is directed to a base suitable for connection to an instrument chassis.
One aspect of the present invention is directed to a construction vehicle. The construction vehicle of the present invention includes a base unit, a chassis, and a trench excavator assembly. The base unit has a first end and a second end, and includes a platform and a plurality of ground driving members. The platform extends from the first end of the base unit and is configured to be a platform for an operator in a standing posture. The ground driving member is installed between the platform and the second end of the base unit. The chassis turns about a substantially vertical axis. The trench excavator assembly (assembly) includes a trench excavator arm and is operably connected to the carriage. The Mizobori overhanging arm pivots about a substantially horizontal axis.
Another aspect of the present invention is directed to an articulated construction vehicle. The articulate construction vehicle of the present invention includes a base unit, an operator station, a connection node, and an instrument chassis. The base unit is provided with a front end portion and a rear end portion, and has a power unit and at least one ground drive member. The power unit is configured to be suitable for powering the construction vehicle. The ground surface driving member is supplied with power by a power device and has a configuration suitable for supplying mobility to the construction vehicle. The operator station is suitable for projecting from the rear end of the base unit so that the vehicle can be operated while walking behind the vehicle or standing on the vehicle. The connection node includes a work mounting plate and a swivel attachment. The pivot attachment is operably connected to the front end of the base unit so that the articulation node is pivotally connected to the base unit about a substantially vertical axis. The instrument chassis can be detachably attached to the work mounting plate at the connection node. The instrument chassis has at least one ground support member. The ground support member is configured to provide mobility and support to the instrument chassis and base unit.
Another aspect of the present invention is directed to a base unit suitable for connection to an instrument chassis. The instrument chassis includes at least one ground support member suitable for providing mobility and support to the base unit and instrument chassis. The base unit includes an upright operation platform, at least one ground driving member, and a connection node. The operating platform extends from the first end of the base unit. The ground drive member is configured to provide support mobility to the base unit. The pivoting attachment is operatively connected to the second end of the base unit such that the articulation node is pivotally connected to the base unit about a vertical axis. The work mounting plate has a structure suitable for mounting on the instrument chassis.
Here, an overview of the entire drawing and an attention to FIG. 1 in particular illustrate the basic structure of an articulated tool carrier according to the present invention. A tool carrier, i.e., a construction vehicle, is indicated by reference numeral 10 and includes a base unit 12 (illustrated as a substructure for purposes of illustration in this case), an articulated node 14 and a plurality of instrument chassis 16. One of them. The connection node 14 pivotally connects the base unit 12 to the instrument chassis 16.
The base unit 12 is provided with a first end 18 and a second end 20. The base unit 12 includes an operator platform 22, a plurality of ground drive members 24, and at least one swivel plate 26. The platform 22 is installed at a position of the first end 18 of the base unit 12 close to the ground surface driving member 24, and projects from the first end 18. The platform 22 provides a scaffold for the operator to stand up and operate the tool carrier 10 in the manner described below. The ground drive member 24 preferably comprises some combination of wheels or catapillas. At least one swivel plate 26 is installed at the second end 20 of the base unit 12 and protrudes therefrom. The swivel plate 26 has a configuration suitable for providing a point where the base unit 12 is connected to the connection node 14. In order to obtain more structural integrity, it is preferred that there are two swivel plates 26. The pin receiving part 28 of the turning plate 26 functions as a turning point on the vertical plane.
The articulation node 14 includes a pivot pin 30, a pin receiving portion 32, a mounting plate 34, and a steering assembly 36. The pivot pin 30 is inserted through the pin receiving portion 28 of the base unit 12 and the opening of the connection node 14. The pivot pin 30 facilitates connection between the base unit 12 and the connection node 14 and functions as a pivot point about a substantially vertical axis formed by the pin. The mounting plate 34 functions as a connection point of the instrument chassis 16. The mounting plate 34 is preferably constructed so that the instrument chassis 16 can be quickly attached and detached.
The articulation node 14 can be pivoted relative to the base unit 12 by operation of the steering assembly 36. The steering assembly 36 preferably comprises a hydraulic steering cylinder 38, but other steering means are conceivable. The steering cylinder 38 is provided with a first end fixed to the connection node 14 and a second end that can be fixed to the base unit 12. Due to the expansion and contraction of the cylinder 38, the mounting plate 34 is rotated relative to the base unit 12. As a result, it is possible to achieve a tightly connected steering by turning around a vertical axis placed around the tool carrier 10. As an alternative example, the articulate steering method can be used by adjusting it with other forms of steering. Specific examples of such steering include skid steering, rear wheel steering, front wheel steering, and attachment assist steering. and so on. In addition, the connection node 14 may vibrate about a long axis that is substantially parallel to the moving direction. If the action of such vibration is given, it is possible to improve the ability to follow the ground.
The instrument chassis 16 can be connected to a mounting plate 34 at the connection node 14. The chassis 16 is preferably configured to be quickly and detachably mounted on the mounting plate 34. As an alternative example, the chassis may be secured using common fasteners. The chassis 16 includes at least one ground support member 40. The ground support member 40 is a non-powered follower wheel or a power drive wheel, or a caterpillar, and functions so as to perform better movement. As an alternative example, the ground support member 40 may be a tool as described below. The chassis 16 may include one or more kinds of various tools as will be described later. The chassis 16 may be interchangeable with another chassis having alternative tools or applications to those described above. As a result, the wheel base of the tool carrier 10 and the wheel support (distance between both wheels) of the ground support member 40 of the chassis 16 optimize the function and stability of the entire vehicle as a function of the installed tool configuration. There is a possibility of various dimensions.
Referring now to FIG. 2, there is illustrated an embodiment of the tool carrier device 10, where the instrument chassis 16 includes a trench machine assembly 44. The base unit 12 includes an operation station 46, at least one ground driving member 24, and an engine room 48. The operation station 46 includes the platform 22 and a control system 50. Platform 22 is substantially centered at the first end of base unit 12 and overhangs from the first end. The platform 22 is suitable for allowing the operator to operate the control system 50 upright on the tool carrier 10 without disturbing the field of view of the chassis 16 and the tool. . The weight of the operator standing on the platform 22 increases the traction friction between the individual ground drive members 24 and the ground. In an alternative embodiment, all or part of the functionality of the control system 50 is accomplished using a direct connection control system or a remote control system, allowing the operator to control the tool carrier 10 remotely. . As an alternative example, the operator station 46 may be configured to allow the operator to walk behind or beside the tool carrier 10. You can also.
The ground drive member 24 is configured to give the tool carrier 10 traction mobility, and more specifically, to provide the traction mobility for the base unit section 12. ing. In the preferred embodiment illustrated in FIG. 2, the base unit 12 includes two ground drive members 24. As illustrated, the two ground drive members 24 are wheels, and rubber wheels are preferably attached to these wheels.
As an alternative example, as illustrated in FIG. 3, the ground surface driving member 24 a and the ground support member 40 a may be a rubber catapillar or a steel catapillar, or other than these, the vehicle is moved across the ground surface. It may be a mechanism used for the purpose. The disclosed ground drive member 24a and ground support member 40a are all some combination of powered or non-powered wheels or catapillas. For example, FIG. 4 illustrates that the tool carrier 10 is provided with certain combinations of catapillas 24b and wheels 40b. As shown in the figure, the addition of a caterpillar 24b to the base unit 12 provides further stability to the base unit even when the chassis 16 must be operated without any attachments. As another means of stabilizing the base unit 12 to accommodate movement connected to the chassis 16 or movement engaged with the chassis 16, transient ground contact stabilization members, such as wheels or skids, etc. There is a way to use. This temporary member (not shown) may be removed from the base unit 12, or may be stored storable when not in use.
Referring again to FIG. 3, the engine compartment 48 includes an engine enclosure 52, an engine 54 or power unit, at least one ground drive member drive motor 56, and a base unit power connection 58. . As shown in the figure, the power connection 58 is a hydraulic pump, but as an alternative, the power connection may be a power system or a pneumatic system driven by the engine 54, an on-board battery, or an external power source. Also good. The engine enclosure 52 protects the engine 54 from damage caused by external forces, and provides a barrier between the engine and the operator or person watching the construction. The engine 54 is configured to provide power to various machine components and hydraulic components of the tool vehicle 10. The power provided by the engine 54 is supplied to each operating member of the chassis 16 by the base unit power connection 48, and at this time, a conventionally known hydraulic connection apparatus and power connection apparatus for the chassis are used. (Both not shown). The steering assembly 36 is also powered by the power connection 58 and is controlled by an operator operating the control system 50.
The ground driving member driving motor 56 is configured to operate at least one of the ground driving members 24 a using the power from the engine 54. Each of the ground drive members 24 a preferably has a separate motor 56. Those skilled in the art will recognize that this allows the base unit 12 to be moved without the use of an axle. Furthermore, the lack of the axle enables the engine 54 to be installed at a lower position in the engine room 48, and the center of gravity of the base unit 12 is lowered without increasing the wheel distance. Can do.
In the present invention, there is also a function to prepare for various hydraulic circuits by having an individual motor 56 for each wheel. By selectively installing the drive motor 56 in either a series circuit or a parallel circuit, the speed performance and torque performance can be varied. In addition, the hydraulic circuit can be arranged so that the individual motor 56 for each wheel is fixed in one direction, and is preferably arranged in an unfixed position for independent operation.
Referring now to FIG. 5, various shapes of the tool carrier 10 are illustrated in a flow chart format and illustrate various replaceable embodiments of the present invention. As disclosed up to the previous stage, the tool transport vehicle 10 includes a base unit 12, a connection node 14, and one of a plurality of instrument chassis 16. FIG. 5 illustrates the breakdown of various possible configurations of the chassis 16. In one embodiment, the chassis is a dedicated instrument chassis 60. The dedicated instrument chassis 60 is preferably fixed to the connection node 14. As an alternative example, the dedicated instrument chassis 60 is configured to be quickly attached to the connection node 14 or formed integrally with the connection node 14.
Referring now again to FIG. 2, a specific embodiment of a dedicated instrument chassis 60 is illustrated. The dedicated instrument cart 60 includes at least one ground support member 40, a power receiving portion 62 such as a hydraulic motor, and a dedicated instrument 66. In FIG. Has been. The power receiving portion 62 can be connected to the base unit power connection member 58 and has a configuration suitable for supplying power to the dedicated instrument chassis 60. A variety of tool constructions can be considered for the dedicated instrument 66. Specific examples thereof include a ditching machine, a vibrating rod, a cutter wheel, a mower, and an excavator. FIG. 2 exemplifies that the groove machine assembly 44 of the dedicated instrument chassis 60 is provided with one follower wheel 40 and a helical auger 68. The trench excavator assembly 44 includes a trench trench extending arm 70 and a drilling chain 72.
The ditcher assembly 44 can be pivoted about a horizontal axis using a hydraulic cylinder 74. The excavation chain 72 is rotatably connected to the periphery of the trench chain extending arm 70 and is driven by a hydraulic motor 62. When the tool carrier 10 is operating as a trench machine, it normally moves in the direction of the base and effectively follows the base unit 12. In operation, the ditch chain extension arm 70 is swiveled by the cylinder 74 toward the ground where the ditch is to be provided. The soil moved by the rotation of the excavation chain 72 is accumulated near the vehicle 10. The spiral auger 68 rotates the means for removing the soil to the sides (both sides) of the chassis 60 so that the means does not hinder the progress of the tool carrier 10 while digging the groove. . The helical auger 68 also prevents the soil from falling back into the groove.
In the prior art, a small ditcher without a steering means was installed, and the direction and location were changed using physical force. In the present invention, the articulation node 14 provides the ability to operate simultaneously while moving to the vehicle 10 to make the operation easier and reduce both the time required for the work and the degree of surface damage. ing.
FIG. 6 illustrates one embodiment of the configuration of the present invention in which the dedicated instrument 66 includes a mower assembly 76. As shown, the mower assembly 76 is attached to the base unit 12 at the connection node 14. The mower assembly 76 includes a mower blade (not shown), a mower deck 77, and a ground support member 40c. The ground support member 40c is preferably an elevated moving pulley. The elevated moving pulley 40c is either free floating or operates in conjunction with articulated steering. More preferably, the elevated moving pulley 40c is used to support the mower deck 77 and to control the height of the deck. The blade of the mower is powered by the hydraulic motor that receives power from the base unit 12 via the base unit power connection 58.
Referring now to FIG. 7, yet another embodiment of the configuration of the present invention is illustrated, in which a dedicated instrument 66 is provided with a vibrating rod assembly 78. In this configuration, the dedicated instrument chassis 60 has two wheels. The two wheels 40 may be non-powered, or alternatively, may receive power from the power connection 58 to provide four-wheel drive performance to the tool carrier 10.
Referring now to FIG. 8, one embodiment of the present invention in which the dedicated instrument 66 is a small roller 80 is illustrated. In this configuration, the attachment functions as both the dedicated instrument 66 and the ground support member 40. The roller 80 may be either non-vibration type or vibration type, and may be either rotational drive type or free rotation type.
Referring again to FIG. 5, in yet another alternative embodiment, the specialized instrument chassis 60 may be configured to connect to a replaceable attachment 82. One possible embodiment of the present invention is illustrated in FIG. As illustrated in the figure, the dedicated instrument chassis 60 is for use with at least one ground support member 40, a power receiving portion 62 (shown is a hydraulic motor), and a replaceable attachment 82. The special instrument 66 is provided. FIG. 9 illustrates that the special instrument 66 of the special instrument chassis 60 is in the form of an aerial work arm 84. The aerial work arm 84 includes one or more movable lift arms, and a movable replaceable attachment mounting plate 86 is provided at the distal end of the lift arms. Attached to the mounting plate 86 is any pallet fork, bucket-type transporter, rotating brush, cultivator, rock drill, trenching machine, or any other attachment 82 that has attachment capability. it can. The attachment 82 may be either non-powered or powered. The illustrated attachment 82 is a bucket-type transporter.
Referring once again to FIG. 5, an alternative configuration suitable for the tool carrier 10 is illustrated. In this embodiment, the instrument cart 16 includes a general-purpose instrument cart 90. The universal instrument carriage 90 may be fixed to the connection node 14, may be connected by an immediate attachment device, or may be integrated with the connection node. The universal instrument carriage 90 is attached to an integrated modular instrument 92. As an alternative, the universal instrument cart 90 is attached to a modular instrument 92 that is configured to connect to a replaceable attachment 82. One basic structure of this embodiment of the present invention is illustrated in FIG. The universal instrument carriage 90 has at least one ground support member 40 and a mounting surface 96. The mounting surface 96 is the upper surface of the universal chassis 90 and preferably functions as a generally horizontal connection point. The attachment means of the attachment surface 96 may comprise an immediate attachment or may use a conventional fixture.
As illustrated in FIG. 11, the mounting surface 96 is configured to be suitable for mounting to a plurality of modular instruments 92. In FIG. 11, the modular instrument 92 includes a cutter wheel 98. The cutter wheel 98 is attached to a general-purpose instrument chassis by an attachment surface 96. This embodiment is flexible enough to replace multiple separate modular instruments 92, such as a collection box, vibratory excavator, excavator, or ditcher, etc. . Depending on the type of modular instrument 92 used, in addition to the ground support member 100 of the instrument chassis 90, the instrument may also have its own ground support member 100. The ground support member 100 added in this way may be either a power type or a non-power type.
As illustrated in FIG. 12, the modular instrument 92 includes an accumulation box 102. The modular device 92 includes its own additional ground support member 100. As shown, the additional ground support member 100 is part of a modular instrument 92 that is secured to the universal instrument chassis 90, resulting in six ground support members 24, 40, 100 being the vehicle 10. Will be provided. As an alternative example, the above-mentioned ground support members 24, 40, and 100 may be provided with a hydraulically driven caterpillar (one or more).
FIG. 13 illustrates an alternative embodiment of a modular instrument 92 attached to a universal instrument chassis 90. In this embodiment, the modular instrument 92 includes an excavator 104 and a push blade 106. Using articulated steering in conjunction with excavator 104 swinging can increase the size of the work area without the need to reduce the position of tool carrier 10. The push blade 106 is configured to be suitable for performing functions such as pushing loose materials such as soil and stabilizing the device during operation of the excavator. As shown, the pusher blade 106 includes a stabilizer 108 that provides an additional stabilizing effect. Stabilizer 108 can be folded, or can open from push blade 106 and extend to engage the face of the blade. Yet another stabilizer may be added to the base unit 12 to increase stability.
As illustrated in FIG. 13, the modular instrument 92 includes a separate control system 50a due to the numerous controls required to operate this type of tool. As an alternative example, the control function may be achieved by using a combination of the control system 50 attached to the base unit 12 and the control system 50a attached to the modular instrument 92.
Referring to FIG. 14, the modular instrument 92 is configured for use with a plurality of attachments 82. In one particularly useful embodiment, the modular instrument 92 is illustrated as a tower 110 with a lift arm. As described above, the attachment 82 may be any of a plurality of attachments such as a pallet fork, a rotary brush, a bucket-type transporter, and the like. Illustrated in FIG. 14 is a bucket-type transporter. One skilled in the art will recognize that this particular embodiment allows the tool carrier 10 to make three potential changes, i.e., the chassis 16 may be a different dedicated chassis 60 or universal chassis. 90 may be attached to the mounting plate 34 of the connection node 14, the modular instrument 92 may be replaced with a different modular instrument member and attached to the mounting surface 96, or the current module The attachment 82 attached to the expression device 92 can also be replaced.
Various modifications can be made to the design and operation of the present invention without departing from the spirit of the invention. For example, a tool may be provided at both ends of the tool carrier 10 by attaching a plurality of tools or a plurality of attachment members to the base unit 12. Further, the instrument as described herein may be a combination of tools. Accordingly, the main preferred configurations and modes of operation of the present invention have been described in the manner illustrated above, which can be considered presently representative of the best embodiment. It should be construed that the invention can be implemented in a manner different from that illustrated.
FIG. 6 is a cutaway perspective view illustrating a lower structure of a tool carrier equipped with an example of a base unit, a connection node, and a plurality of replaceable instrument chassis according to the present invention. It is the perspective view which illustrated the tool carrier which has a ditching machine assembly. It is the perspective view which illustrated the endless track tool carrier which attached the general purpose instrument stand. It is the perspective view which illustrated the place which attached the tire to the instrument stand of the tool carrier of FIG. 3 is a flowchart of various embodiments of a tool carrier according to the present invention. It is the perspective view which illustrated that the tool transport vehicle is provided with the exclusive lawn mower attachment. It is the perspective view which illustrated that the tool carrier vehicle was equipped with the exclusive vibrating rod attachment. It is the perspective view which illustrated that the tool transport vehicle is provided with the exclusive compaction roller attachment. FIG. 6 is a perspective view illustrating the tool carrier having a dedicated lift arm attachment configured to receive a replaceable instrument. It is the cutaway perspective view which illustrated that the tool carrier is provided with one type of a base unit, a connection node, and a plurality of general purpose chassis. It is the figure which illustrated that the tool carrier vehicle was equipped with the general-purpose instrument stand and the attached cutter wheel. It is the perspective view which illustrated that the tool carrier vehicle was equipped with the general purpose instrument stand and the attached integrated box. It is the perspective view which illustrated that the tool carrier vehicle was equipped with the general-purpose instrument stand and the attached excavator. It is the perspective view which illustrated that the tool carrier was provided with the attachment lift arm suitable for using together with a general-purpose instrument stand and various exchangeable attachments.
A construction vehicle,
A base unit provided with a first end and a second end;
(A) a platform having a configuration suitable for supporting an operator who stands out from the first end of the base unit;
(A) a plurality of ground drive members installed between the platform and the second end of the base unit;
(C) having at least one ground support member, and having a chassis that is pivotally connected to the second end of the base unit and pivots about a substantially vertical axis;
The construction vehicle is
A trench excavator assembly operably connected to the chassis and provided with a trench excavator arm configured to pivot about a substantially horizontal axis;
A construction vehicle characterized by that.
The construction vehicle according to claim 1, wherein the ground driving member of the base unit has a configuration suitable for propelling the construction vehicle.
The construction vehicle according to claim 2, wherein the ground support member of the chassis is configured to propel the construction vehicle.
The construction according to claim 2, wherein the construction vehicle further comprises a plurality of drive motors, and the ground drive members of the base unit are each powered by one of the motors. vehicle.
The construction vehicle according to claim 2, wherein at least one of the ground driving members of the base unit is equipped with a rubber tire.
The construction vehicle according to claim 1, further comprising a connection mounting portion having a configuration suitable for pivotally connecting the chassis to the base unit.
The construction vehicle according to claim 6, wherein the chassis is separated from the base unit at a position of the connecting attachment portion.
The construction vehicle according to claim 1, wherein the ditcher assembly is detachably attached to the chassis.
A concatenated construction vehicle,
A front end and a rear end are provided, and a power unit having a configuration suitable for supplying power to the articulated construction vehicle, and power supplied by the power unit and providing mobility to the construction vehicle. A base unit having at least one ground drive member in a suitable configuration;
Suitable for projecting from the rear end of the base unit so that the operator can operate the construction vehicle while walking behind the construction vehicle or standing upright on the construction vehicle. A configuration operator station; and
A work mounting plate and a swivel mounting member are provided, and when the swivel mounting member is operably connected to the front end of the base unit, the base unit is pivotable about an axis substantially perpendicular to the base unit. A connection node connected to
An instrument chassis that is removably attachable to the work attachment plate of the connection node and is provided with at least one ground support member, the at least one ground support member comprising the instrument chassis and the instrument chassis It is suitable for providing mobility and support to the base unit.
A connected construction vehicle characterized by that.
The articulated construction vehicle according to claim 9, wherein each of the ground driving members is a wheel.
The articulated construction vehicle according to claim 9, wherein the mounting plate has a configuration suitable for immediate mounting on the instrument chassis.
The articulated construction vehicle according to claim 9, wherein the instrument chassis is equipped with a vibrating rod.
The articulated vehicle according to claim 9, wherein the instrument chassis is equipped with a ditch machine.
The articulated vehicle according to claim 9, wherein the instrument chassis is equipped with an excavator.
The articulated construction vehicle according to claim 9, further comprising a tool that can be attached to the instrument stand.
The articulated construction vehicle according to claim 15, wherein a specific example of the tool is a trench excavator assembly.
10. The articulated vehicle further comprises a plurality of drive motors, and the ground drive members of the base unit are each powered by one of the plurality of motors. The articulated construction vehicle described.
The articulated construction vehicle according to claim 9, wherein at least one of the ground support members of the instrument chassis is connected to and can be driven by the power unit.
The articulated vehicle according to claim 9, wherein the instrument chassis is powered by the base unit and controlled by the operator station.
A base unit suitably configured to connect to the instrument chassis,
The instrument chassis is provided with at least one ground support member, and the ground support member is configured to provide mobility and support to the base unit and the instrument chassis.
An upright operator platform extending from the first end of the base unit;
At least one ground drive member suitably configured to provide support and mobility to the base unit;
And a connection node provided with a work mounting plate and a swivel mounting member, wherein the connection node is substantially connected to the base unit in operatively connecting the swivel mounting member to the second end of the base unit. Is pivotally connected about a vertical axis, and the work mounting plate is configured to be mounted on the instrument chassis.
Base unit characterized by that.
JP2008545807A 2005-12-13 2006-12-13 Small machine tool transporter with articulated nodes Pending JP2009519393A (en)
US75041905P true 2005-12-13 2005-12-13
PCT/US2006/047709 WO2007070638A2 (en) 2005-12-13 2006-12-13 Compact tool carrier with articulation joint
JP2009519393A true JP2009519393A (en) 2009-05-14
ID=38163523
JP2008545807A Pending JP2009519393A (en) 2005-12-13 2006-12-13 Small machine tool transporter with articulated nodes
US (2) US8485287B2 (en)
EP (2) EP1963583A4 (en)
JP (1) JP2009519393A (en)
KR (1) KR20080077389A (en)
CN (1) CN101331277B (en)
AU (1) AU2006326383B2 (en)
CA (1) CA2631668C (en)
HK (1) HK1127865A1 (en)
WO (1) WO2007070638A2 (en)
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2006-12-13 KR KR1020087016115A patent/KR20080077389A/en not_active Application Discontinuation
2006-12-13 CN CN 200680047093 patent/CN101331277B/en not_active IP Right Cessation
2006-12-13 AU AU2006326383A patent/AU2006326383B2/en not_active Ceased
2006-12-13 EP EP06845420A patent/EP1963583A4/en not_active Withdrawn
2006-12-13 US US11/610,428 patent/US8485287B2/en active Active
2006-12-13 US US11/610,435 patent/US20070131437A1/en not_active Abandoned
2006-12-13 WO PCT/US2006/047709 patent/WO2007070638A2/en active Application Filing
2006-12-13 CA CA 2631668 patent/CA2631668C/en active Active
2006-12-13 JP JP2008545807A patent/JP2009519393A/en active Pending
2006-12-13 EP EP11169187.9A patent/EP2368787B1/en active Active
2009-06-11 HK HK09105262A patent/HK1127865A1/en unknown
CA2631668A1 (en) 2007-06-21
CA2631668C (en) 2011-11-22
WO2007070638A3 (en) 2007-08-02
EP2368787B1 (en) 2014-05-14
EP2368787A3 (en) 2012-05-02
HK1127865A1 (en) 2012-08-24
WO2007070638A2 (en) 2007-06-21
AU2006326383B2 (en) 2011-06-16
US20070131437A1 (en) 2007-06-14
EP1963583A4 (en) 2010-12-22
US8485287B2 (en) 2013-07-16
CN101331277B (en) 2012-02-22
AU2006326383A1 (en) 2007-06-21
EP2368787A2 (en) 2011-09-28
CN101331277A (en) 2008-12-24
US20070132204A1 (en) 2007-06-14
KR20080077389A (en) 2008-08-22
EP1963583A2 (en) 2008-09-03
ES2251140T3 (en) 2006-04-16 Flasher with ability to flash edges.
EP0957207A2 (en) 1999-11-17 Sweeper with auxiliary brush and auxiliary lip