Patent Description:
A carrying robot is a kind of equipment used in the field of automatic material carrying, which has many advantages such as high degree of automation, flexible application, safety and reliability, high efficiency and convenient maintenance. Therefore, the carrying robot is widely used in logistics and transportation occasions such as automotive manufacturing industry, food industry, tobacco industry, construction machinery industry, and the carrying robot has also made achievements in various public service places such as airports, hospitals and office buildings. These advantages also make the carrying robot become the key equipment in a modern logistics system and become one of the important members of the "machine substituting labor" program.

Because KIVA Company has put forward a concept of "shelf to person" and achieved great success, and its structure and method are described in detail in an American patent NO. Many unmanned carrying robots with the concept of "shelf to person" arise in China, and good results have been achieved. However, in order to take a piece of goods, the KIVA robot needs to carry a whole shelf to a picking area, resulting in a great waste of resources.

Therefore, in order to overcome the disadvantage that the KIVA robot can only take one piece of goods at a time, those skilled in the art are committed to developing a robot for carrying a container which can carry a variety of goods at a time and improve the carrying efficiency of the carrying robot. <CIT> discloses a robot drive unit (RDU), including an arm positioner that is mounted on a chassis of the RDU and that adjusts position of an arm unit in a vertical plane. The arm unit includes at least one arm to hold a product and an arm holder to hold the at least one arm. The arm positioner enables the arm unit to be moved along arm supporting structure. The arm unit includes an arm that further includes a base arm and an extendable arm, which is housed in the base arm. The extendable arm can be extended and retracted, which enables retrieving and storing the products. When extended, the extendable arm extends beyond the chassis of the RDU. The extendable arm can include holders.

In view of the above disadvantages of the conventional technology, the technical issue to be addressed by the present application is how to improve the carrying efficiency of a carrying robot. Since it is a container to be carried and the volume and weight of the container are much smaller than that of a shelf, multiple containers can be carried at a time. A single container stores at least one kind of goods, so a variety of goods can be carried at a time.

In order to achieve the above object, a robot for carrying a container is provided according to the present application, which includes a drive unit, a container storage unit and a container transport unit, where the drive unit carries the container storage unit and the container transport unit to jointly move. The container storage unit includes one or more container storage spaces, and the container transport unit is arranged at one side of the container storage unit and is configured to transport the container between the container storage space and the shelf. The container storage unit includes support rails, pallets and reinforcing ribs, and the support rails, the pallets and the reinforcing ribs are connected with each other to form one or more container storage spaces. The container transport unit includes a lifting device, a rotating device and a telescopic fork tooth, one end of the lifting device is connected with the support rails and is slidable up and down along a vertical direction of the support rails, and another end of the lifting device is connected with the telescopic fork tooth through the rotating device, the telescopic fork tooth is configured to extend and retract along a telescopic direction, the rotating device drives the telescopic fork tooth to rotate, such that a telescopic direction of the telescopic fork tooth rotates.

Further, the drive unit includes a chassis frame and drive wheels configured to drive the robot to move or stop.

Further, the motion includes advance, reverse, turn and in-situ rotation.

Further, two or more drive wheels are provided.

Further, the pallets are configured to separate the storage spaces.

According to the invention, the container transport unit includes a lifting device, a rotating device and a telescopic device, where one end of the lifting device is connected with the support rails and can slide up and down along a vertical direction of the support rails, and the other end of the lifting device is connected with the telescopic device through the rotating device.

Further, the robot for carrying a container further includes the container, the container storage spaces and the container have machine-readable codes, and the container transport unit further includes a positioning sensor and a pose sensor.

Further, the machine-readable code is a barcode or a two-dimensional barcode or a character string or an RFID.

Further, the positioning sensor is configured to detect a position of the container, and the positioning sensor is a vision sensor or a radio frequency sensor.

Further, the pose sensor is configured to detect a positional posture of the container on the container transport unit, and the pose sensor is a vision sensor or a radio frequency sensor.

Further, the pallet is a plate with an integral surface or the pallet is hollowed or partitioned.

The process of the robot for carrying a container according to the present application carrying the container to the container storage unit is as follows, the carrying robot moves the container transport unit to a specified position through the lifting device, and rotates the telescopic fork tooth to a specified angle through the rotating device, then extends the telescopic fork tooth to a position below the container to be transported, then lifts the container through the lifting device, then retracts the container through the telescopic fork tooth, then rotates the telescopic fork tooth and the container to another specified angle through the rotating device, then moves the container to a position above the pallet through the telescopic fork tooth, then lowers the container through the lifting device to place the container on the pallet, and finally retracts the telescopic fork tooth. Therefore, the robot for carrying a container according to present application can transport a variety of goods at a time, and has high working efficiency and low energy consumption.

The concept, specific structure and technical effects of the present application are further described in conjunction with the drawings below to fully understand the objects, features and effects of the present application.

Two preferred embodiments of the present application are described below with reference to the drawings of the specification to make the technical contents of the embodiments clearer and easier to understand. The present application may be embodied by many different forms of embodiments, and the scope of protection of the present application is not limited to the embodiments disclosed herein.

In the drawings, components with the same structure are represented by the same reference numerals, and components with similar structures or functions are represented by similar reference numerals. The dimensions and thickness of each component shown in the drawings are not shown to scale, and the present application does not limit the dimensions and thickness of each component. In order to make the illustrations clearer, the thickness of the components is appropriately exaggerated in some places of the drawings.

When some components are described as 'on another component', the components may be placed directly on another component, or there may be an intermediate component, the components are placed on the intermediate component, and the intermediate component is placed on another component. When some components are described as 'mounted to' or 'connected to' another component, the components may be directly 'mounted to' or 'connected to' the other component, or there may be an intermediate component, and the components are 'mounted to' or 'connected to' another component through the intermediate component.

As shown in <FIG>, a robot for carrying a container includes a drive unit <NUM>, a container storage unit <NUM> and a container transport unit <NUM>.

The drive unit <NUM> includes a chassis frame <NUM> and drive wheels <NUM>, where two drive wheels <NUM> are provided and symmetrically mounted on two sides of the chassis frame <NUM>. By the rotation of the drive wheels <NUM>, the advance, reverse, turn and in-situ rotation of the robot can be realized.

The container storage unit <NUM> includes support rails <NUM>, pallets <NUM> and reinforcing ribs <NUM>. The support rails <NUM> are located above the drive unit <NUM>. The support rails <NUM> are connected to each other by the pallets <NUM> and the reinforcing ribs <NUM>, and the pallets <NUM> are configured to stack the containers.

The container storage unit <NUM> can store multiple containers.

Each of the pallets <NUM> is separated in the middle.

The container transport unit <NUM> includes a frame <NUM>, a lifting device <NUM>, a telescopic fork tooth <NUM> and a rotating device <NUM>. One end of the lifting device <NUM> is connected with the support rails <NUM> and can slide up and down along a vertical direction of the support rails <NUM>, and another end is connected with the telescopic fork tooth <NUM> through the rotating device <NUM>.

The telescopic fork tooth <NUM> can rotate along the z-axis through the rotating device <NUM>.

The telescopic fork tooth <NUM> extends or retracts along the x direction. If the rotating device <NUM> drives the telescopic fork tooth <NUM> to rotate, a telescopic direction of the telescopic fork tooth <NUM> also rotates.

The container transport unit <NUM> further includes a pose sensor <NUM> configured to identify a posture of the container above the telescopic fork tooth <NUM>, and a positioning sensor <NUM> configured to detect a position of the container.

The pose sensor <NUM> may be a vision sensor or other sensor that can obtain pose information.

The positioning sensor <NUM> may be a vision sensor or other sensor that can obtain pose information.

The process of the robot for carrying a container carrying the container <NUM> to the container storage unit <NUM> is as follows, the robot moves the container transport unit <NUM> to a specified position through the lifting device <NUM>, and rotates the telescopic fork tooth <NUM> to a specified angle through the rotating device <NUM>, then extends the telescopic fork tooth <NUM> to a position below the container <NUM> to be transported, then lifts the container <NUM> through the lifting device <NUM>, then retracts the container <NUM> through the telescopic fork tooth <NUM>, then rotates the telescopic fork tooth <NUM> and the container <NUM> to another specified angle through the rotating device <NUM>, then moves the container <NUM> to a position above the pallet <NUM> through the telescopic fork tooth <NUM>, then lowers the container <NUM> through the lifting device <NUM> to place the container on the pallet <NUM>, and finally retracts the telescopic fork tooth <NUM>.

As shown in <FIG> and <FIG>, a robot for carrying a container includes a drive unit <NUM>, a container storage unit <NUM> and a container transport unit <NUM>.

The drive unit <NUM> includes a chassis frame <NUM> and drive wheels <NUM>, where two drive wheels <NUM> are provided and symmetrically mounted on both sides of the chassis frame <NUM>. By the rotation of the drive wheels <NUM>, the advance, reverse, turn and in-situ rotation of the robot can be realized.

Each of the pallets <NUM> is a flat plate connected with the support rails <NUM> on both sides.

The container transport unit <NUM> includes a frame <NUM>, a lifting device <NUM>, a telescopic fork tooth <NUM> and a rotating device <NUM>. One end of the lifting device <NUM> is connected with the support rails <NUM> and can slide up and down along a vertical direction of the support rails <NUM>, and the other end is connected with the telescopic fork tooth <NUM> through the rotating device <NUM>.

The telescopic fork tooth <NUM> can extend or retract along the x direction. If the rotating device <NUM> drives the telescopic fork tooth <NUM> to rotate, a telescopic direction of the telescopic fork tooth <NUM> also rotates.

The pose sensor <NUM> may be a vision sensor or other sensor that can obtain pose information, such as a radio frequency sensor.

The positioning sensor <NUM> may be a vision sensor or other sensor that can obtain pose information, such a radio frequency sensor.

Claim 1:
A robot for carrying a container, comprising a drive unit (<NUM>), a container storage unit (<NUM>) and a container transport unit (<NUM>), wherein the drive unit (<NUM>) is configured to carry the container storage unit (<NUM>) and the container transport unit (<NUM>) to jointly move; and the container storage unit (<NUM>) comprises one or more container storage spaces; and
the container transport unit (<NUM>) is arranged at one side of the container storage unit (<NUM>) and is configured to transport the container between the container storage spaces and a shelf;
the container storage unit (<NUM>) comprises support rails (<NUM>), pallets (<NUM>) and reinforcing ribs, and the support rails (<NUM>), the pallets (<NUM>) and the reinforcing ribs are connected with each other to form one or more container storage spaces, and
the container transport unit (<NUM>) comprises a lifting device (<NUM>), a rotating device (<NUM>) and a telescopic fork tooth, one end of the lifting device (<NUM>) is connected with the support rails (<NUM>) and is slidable up and down along a vertical direction of the support rails (<NUM>), characterized in that
another end of the lifting device (<NUM>) is connected with the telescopic fork tooth through the rotating device (<NUM>), the telescopic fork tooth is configured to extend and retract along a telescopic direction, the rotating device (<NUM>) drives the telescopic fork tooth to rotate, such that the telescopic direction of the telescopic fork tooth rotates.