WO/2016/051540 MANAGEMENT SYSTEM OF WORKING MACHINE, MANAGEMENT METHOD OF WORKING MACHINE, AND WORKING MACHINE||WO||07.04.2016|
||PCT/JP2014/076203||KOMATSU LTD. 株式会社小松製作所||OHTA, Yuhei 大田 悠平|
A management system of a working machine includes: a working machine provided with a communication terminal device having a communication function, a power source which supplies electric power to the communication terminal device, and a switch provided between the power source and the communication terminal device; and a management device which is capable of communicating with the communication terminal device, and which transmits a request command to the communication terminal device, causing the communication terminal device to execute a process making said communication possible. When the communication terminal device receives the request command from the management device, the communication terminal device enters a state in which it accepts the supply of electric power from the power source, until a pre-determined time has elapsed after the switch has been turned from an ON state to an OFF state.
WO/2016/053122 "HULAJBIEGA" WHEELED VEHICLE||WO||07.04.2016|
||PCT/PL2014/000120||DECYLION SP. Z O.O. ||GROCHOWINA, Marcin |
The "Hulajbiega" for rehabilitation and training, comprising a driven track belt made in the form of the endless belt tightened on rollers, lifting mechanism used to change the training load and the handrail to facilitate balancing is characterized in that it comprises the running track fixed to the frame (1), and roller system (3.5), drive shaft (4) and lifting system 7 installed between the foot and the frame for changing the slope of the track belt. Preferably, the belt (2) of the running track has a wedge-shaped ridge on the inner side with a shape corresponding to the groove in the roller (3.5) and the landings for foot for on both sides of the track (2).
WO/2016/053124 THE SYSTEM ASSISTING THE MOVEMENT ON STEEP SURFACES||WO||07.04.2016|
||PCT/PL2014/000122||DECYLION SP. Z O.O. ||GROCHOWINA, Marcin |
The system assisting the movement on steep surfaces provided with a cam mechanism is characterized in that the cam mechanism (5), which is a bistable system holding the wheels (1) in contact with the substrate (2) and the second one raised vertically above the first one, wherein the wheel (1) is connected with the connector (3), through which the axis (4) of the cam mechanism (5) passes in the middle of its length, which is composed of the ellipsoidal cam (8) rigidly fixed on the axle (4), which is positioned in one of two stable positions by means of the clamp (7), through the spring ( 6) resting on the body (9) of the mechanism (4). The ellipsoidal cam (8) and the clamp (7) are made of the material providing a low coefficient of friction.
WO/2016/053123 ROBOT FOR OVER-CEILING SPACE INSPECTION||WO||07.04.2016|
||PCT/PL2014/000121||KTG Sp. z o.o. ||GROCHOWINA, Marcin |
Robot for over-ceiling space inspection fitted with the enclosure with a camera inside with the preview on the operator's computer display is characterized in that it has the gripper (4) with the axis of rotation (3) of the gripper tip (1,2) and the wrist body (6) which has the gripper hinge (5) and the arm (7) connecting the bunch with the robot body. Preferably, it has not less than 6 walking legs (10), where the hind legs move autonomously repeating the movement of the front legs (10). The components of the gripper (4) have a defined range of operation (9), the gripper in the wrist - 110° and the gripper tip - 270 °. The robot has the gripper tip composed of two layers (1,2), wherein the layer (1) is made of an elastic material having a high coefficient of friction, while the layer (2) is made of a hard material having a low coefficient of friction.
WO/2016/042649 WORK VEHICLE AND WORK VEHICLE CONTROL METHOD||WO||24.03.2016|
||PCT/JP2014/074750||KOMATSU LTD. 株式会社小松製作所||KANEKO, Shinji 金子 慎治|
A work vehicle that is provided with a work machine, the work vehicle including: an engine; a variable-capacity, travel hydraulic pump that is driven by the engine; a hydraulic motor that forms a closed circuit between the hydraulic motor and the travel hydraulic pump and that is driven by hydraulic oil that is discharged from the travel hydraulic pump; a driving wheel that is driven by the hydraulic motor; and a control device that is provided with a determining means that determines whether an operator of the work vehicle wants to decelerate, and that, when the determination means has determined that the operator wants to decelerate and when the work vehicle has begun an increase, uses the amount that the vehicle speed of the work vehicle has increased to make a capacity ratio that is found by dividing the capacity of the hydraulic motor by the capacity of the travel hydraulic pump equal to or greater than the value of the ratio at the time that the vehicle speed began the increase.
WO/2016/042648 WORK VEHICLE AND WORK VEHICLE CONTROL METHOD||WO||24.03.2016|
||PCT/JP2014/074749||KOMATSU LTD. 株式会社小松製作所||KANEKO, Shinji 金子 慎治|
A work vehicle that includes: a work machine; an engine; a variable-capacity, travel hydraulic pump that is driven by the engine; a hydraulic motor that forms a closed circuit between the hydraulic motor and the travel hydraulic pump and that is driven by hydraulic oil that is discharged from the travel hydraulic pump; a driving wheel that is driven by the hydraulic motor and that makes the work vehicle travel; a selection switch that detects the operation state of a movement-direction switching device that is for switching between the forward movement and reverse movement of the work vehicle; and a control device that, when the work vehicle is traveling and the selection switch detects a movement-direction switching device reversal operation that is for reversing the movement direction of the work vehicle, sets the relationship between the vehicle speed of the work vehicle and an upper limit for the rotational speed of the engine such that the upper limit becomes larger as the absolute value of the vehicle speed becomes closer to zero and finds the upper limit for the rotational speed of the engine from the set relationship and the vehicle speed of the work vehicle.
WO/2016/033906 THAWING APPARATUS FOR REFRIGERATOR||WO||10.03.2016|
||PCT/CN2014/094802||HISENSE RONSHEN (GUANGDONG) REFRIGERATOR CO., LTD 海信容声（广东）冰箱有限公司||WANG, Haiyan 王海燕|
Disclosed is a thawing apparatus for a refrigerator, comprising a thawing room (1). The thawing room comprises a housing (11), a liner (12) and a door body (13). An electromagnetic wave excitation module (141), an electromagnetic wave high-voltage oscillation module (142) and a monitoring module (143) used for monitoring a food temperature are provided inside the thawing room. The electromagnetic wave excitation module, the electromagnetic wave high-voltage oscillation module and the monitoring module are electrically connected to one another. A first electrode (21) and a second electrode (22) which are used for being in contact with food are provided inside the thawing room. The first and second electrodes are electrically connected to the electromagnetic wave high-voltage oscillation module. A temperature sensor (23) electrically connected to the monitoring module is further provided inside the thawing room. The first and second electrodes release a high-frequency electromagnetic wave for the food in contact therewith, thereby realizing the quick and uniform thawing of frozen food.
WO/2016/029682 UNPOWERED PRESSURE-BEARING STERILIZATION DEVICE FOR AUTOMATICALLY GENERATING AND MIXING CHLORINE DIOXIDE||WO||03.03.2016|
||PCT/CN2015/074431||SHANGHAI CLEAN BAY ENVIRONMENTAL TECHNOLOGY CO.,LTD. 上海科琳宝环境科技有限公司||MO, Zhimin 莫之民|
Provided is an unpowered pressure-bearing sterilization device for automatically generating and mixing chlorine dioxide, comprising a first raw material tank, a second raw material tank, a reactor, a water jet and a cut-off valve; the first raw material tank, second raw material tank and reactor are sealed containers, wherein the reactor is provided with raw material inlets and a discharge outlet, one raw material inlet is connected to the first raw material tank via a first liquid sucking pipe, the first liquid sucking pipe is connected with a first titration valve, the other raw material inlet is connected to the second raw material tank via a second liquid sucking pipe, and the second liquid sucking pipe is connected with a second titration valve. The discharge outlet of the reactor is connected to a suction inlet of the water jet, and the connection pipeline is connected with a cut-off valve. In the device, the addition of the cut-off valve between the suction inlet of the water jet and the reactor achieves the automatic delivery of the raw materials for preparing chlorine dioxide and unpowered automatic preparation of chlorine dioxide, and also achieves to immediately automatically mixing chlorine dioxide and tap water to produce a sterilization water; and when the tap water is turned off, the chemical reaction is spontaneously stopped to prevent the tap water from entering the reactor.
WO/2016/025617 SELF-PROPELLED DEVICE WITH MAGNETIC COUPLING||WO||18.02.2016|
||PCT/US2015/044885||SPHERO, INC. ||BERNSTEIN, Ian H. |
A self-propelled device includes a spherical housing and an internal drive system including one or more motors. The internal drive system acts to provide power to an interior surface of the spherical housing, thereby causing the self-propelled device to move. A biasing assembly can be included to enable the internal drive system to continuously engage an inner surface of the spherical housing. An external accessory magnetically interacts with interior magnetic components through the spherical housing such that as the self-propelled device rotates and maneuvers, the accessory component maintains a positional relationship to a top portion of the self-propelled device.
WO/2016/025047 MAGNETICALLY COUPLED ACCESSORY FOR A SELF-PROPELLED DEVICE||WO||18.02.2016|
||PCT/US2015/030877||SPHERO, Inc. ||BERNSTEIN, Ian H. |
A self-propelled device includes a spherical housing and an internal drive system including one or more motors. The internal drive system acts to provide power to an interior surface of the spherical housing, thereby causing the self-propelled device to move. A biasing mechanism is coupled to the internal drive system and includes a spring and a spring end in contact with the inner surface of the spherical housing. An accessory component magnetically interacts with the biasing mechanism through the spherical housing such that as the self-propelled device rotates along, the accessory component remains stable with respect to the biasing mechanism.