SUMMERY OF THE UTILITY MODEL
For overcoming prior art's defect, the utility model aims to solve the problem that a track intelligent robot that little and climbing and obstacle surmounting ability are strong to the lawn harm is provided.
In order to solve the above problem, the technical scheme of the utility model is that: an intelligent robot, comprising: the shell is hollow inside to form an accommodating cavity; the working module is arranged at the bottom of the shell and used for executing a working task; the walking modules are arranged on two sides of the shell, each walking module comprises a front supporting wheel, a rear supporting wheel and a crawler, and the crawler is wound by taking the front supporting wheel and the rear supporting wheel as two ends; the energy module is arranged in the accommodating cavity; the motor module is arranged in the accommodating cavity and comprises a working motor for driving the working module and a walking motor for driving the walking module; the track has an inner surface in contact with the support wheels, and an outer surface in contact with the ground, the outer surface further having projections, the surfaces of the projections being smooth.
Preferably, the projection is substantially cylindrical or frustoconical.
In a preferred embodiment, the end faces of the cylindrical or truncated-cone-shaped projections are connected to the side faces by arc-shaped faces.
In particular, the ends of the cylindrical or truncated-cone shaped protrusions have a part-spherical shape.
In another preferred embodiment, the projection is part spherical.
Preferably, the protrusions are hemispherical.
Specifically, the protrusions are arranged in a hemispherical shape and are uniformly distributed, so that the grass is minimally rolled in the advancing process of the crawler; if the shape of the grass combing box is cylindrical, the damage to the lawn is effectively reduced, and the grass combing box also has a certain grass combing function.
Preferably, the height of the protrusions is 10mm to 20 mm.
Preferably, the width of the track is 20mm-120mm
Preferably, the distance between the front wheel axle of the front support wheel and the rear wheel axle of the rear support wheel is 200mm-600 mm.
Preferably, the protrusions are evenly distributed.
Compared with the prior art, the utility model discloses an intelligent robot installs the track in both sides, and the track passes through walking motor drive and then drives intelligent robot walking, and the surface of track is provided with evenly distributed's cylindrical or hemispherical arch, and the harm on during operation to the lawn reduces, is difficult for tearing the lawn, and cylindrical arch has the comb grass effect in addition.
Meanwhile, the width of the intelligent robot crawler is set to be less than 10 cm. Because use the track to replace wheelset drive intelligent robot walking, the structure of track and use wheelset very big difference occasionally, the user hardly touches intelligent robot's cutting element to user's safety can obtain fine protection, accords with the requirement of ann's rule. Meanwhile, the width of the crawler belt is set to be smaller than 10mm, and under the condition of the same width of the machine body, the cutting element is arranged to be closer to the outer edge of the machine body, so that the intelligent robot can obtain a larger cutting range. The intelligent robot can cut more residual lawn area outside the boundary line, thereby further reducing the labor burden of the user in nursing the lawn outside the boundary line.
Detailed Description
The following detailed description and technical contents of the present invention are described with reference to the accompanying drawings, however, the accompanying drawings only provide references and descriptions, and do not limit the present invention.
As shown in fig. 1 and 2, an embodiment of the present invention provides an intelligent robot 100. The intelligent robot 100 comprises a shell 10, walking modules 20 positioned on two sides of the shell, a working module arranged at the bottom of the shell, a motor arranged inside the shell 10, a control module for controlling the intelligent robot 100 to automatically work and walk, and an energy module for providing energy. In this embodiment, "set" includes a fixed set or a detachable set. In this embodiment, the motor includes a working motor for driving the working module and a traveling motor for driving the traveling module.
In the description of the present invention, a cartesian coordinate system is established in the orientation of the smart robot 100 shown in fig. 1. The direction of the y-axis is defined as the longitudinal direction of the intelligent robot 100, the positive direction toward the y-axis is defined as the front of the intelligent robot 100, and the negative direction toward the y-axis is defined as the rear of the intelligent robot 100; the direction of the x axis is defined as the lateral direction of the intelligent robot 100, the positive direction toward the x axis is defined as the right side of the intelligent robot 100, and the negative direction toward the x axis is defined as the left side of the intelligent robot 100; the direction of the z-axis is defined as the vertical direction of the intelligent robot 100, the positive direction toward the z-axis is defined as the upper side of the intelligent robot 100, and the negative direction toward the z-axis is defined as the lower side of the intelligent robot 100.
In this embodiment, the housing 10 includes a top cover 12 and a base (not shown), and the top cover 12 and the base form a hollow accommodating cavity. The accommodating cavity is internally provided with a motor, a control module, an energy module and other components which support the intelligent robot 100 to realize various functions. Of course, various sensors may be disposed on or in the housing to assist the intelligent robot 100 in performing various functions.
A walking module 20 is disposed on each side of the housing 10, and is symmetrical to the housing. The traveling module 20 includes front support wheels 203, rear support wheels 201, and a crawler 210. The crawler belt 210 is wound around the front support wheel 203 and the rear support wheel 201 at both ends thereof. The crawler 210 connects the rear support wheels 201 and the front support wheels 203, which are the ground-contacting portions of the entire intelligent robot 100. In the present embodiment, the front support wheels 203 are embodied as drive wheels, and the rear support wheels 201 are embodied as guide wheels. The front support wheel 203 is driven by the motor to rotate, and then the track 210 is driven to continuously rotate around the rear support wheel 201 and the front support wheel 203 to advance, so that the intelligent robot 100 is driven to advance. Of course, the rear support wheel 201 may be other than the embodiment shown in fig. 1, such as a guide support, or a set of wheel sets, and only the end of the track 210 needs to be supported.
In this embodiment, the rear support member 201 is a guide wheel, and the front support member 203 is a driving wheel. The driving wheel is positioned in front of the intelligent robot in the longitudinal direction and serves as a front wheel; the guide wheel is located the longitudinal rear of intelligent robot, as the rear wheel. Of course, the relative longitudinal position relationship between the driving wheel and the guide wheel is not limited, that is, the guide wheel can be used as a front wheel and is positioned in front of the intelligent robot in the longitudinal direction.
The intelligent robot 100 is a machine capable of automatically working and walking, a wheel-type walking structure is changed into a crawler-type walking structure, and the terrain adaptability of the intelligent robot 100 is greatly improved. In this embodiment, the intelligent robot especially indicates an intelligent lawn mower. However, the contact surface of the crawler-type intelligent robot with the lawn is larger than that of the opposite wheel-type intelligent robot, although the pressure applied to the lawn is reduced by the crawler-type intelligent robot with the same weight, the outer surface of the crawler causes rolling and damage to the lawn in a larger area, and the protection to the lawn can be further improved through the arrangement of the crawler structure. In order to compromise the climbing and hinder the performance more simultaneously, the utility model discloses design in order to alleviate the harm to the lawn to the track.
Referring to fig. 2 and 3, in the present embodiment, the crawler 210 is wound around the front support wheels 203 and the rear support wheels 201, and has an inner surface 214 contacting the front support wheels 203 and the rear support wheels 201, and an outer surface 213 contacting the ground. Specifically, the inner surface 214 of the crawler belt is in meshing contact with the front support wheel 203 and the rear support wheel 201, the inner surface has meshing teeth, and the front support wheel 203 and the rear support wheel 201 have meshing portions that are engaged with the meshing teeth. Of course, the front support wheels 203 and the rear support wheels 201 may also be driven by friction or by grooves that engage the inner surface 214, so long as the driving torque for driving the track is provided.
In current structural design, in order to improve track ground gripping performance, the decorative pattern of track surface all generally has sharp-pointed edges and corners, and when track marchd the in-process, grass leaf can be scotched to sharp-pointed edges and corners, and the local grass that makes track type intelligent robot pass through not only is pressed on ground still can have the scotch of a lot of leaves. In order to overcome the problems, the utility model discloses the surface to the track has been designed in order to furthest alleviate its harm to the lawn.
In this embodiment, the crawler 210 of the intelligent robot 100 has an outer surface 213 that contacts the ground. The outer surface has protrusions, and the surfaces of the protrusions are smooth. That is, the surfaces of the protrusions have no corners. Specifically, the surface of the protrusion can be formed by a single arc surface or an arc surface, or can be formed by a plurality of arc surfaces with different curvatures, and the two arc surfaces with different curvatures are in smooth transition; or an irregular arc-shaped surface; the connecting part can also be composed of more than two types of upper surfaces, such as an arc surface, a curved surface and an arc surface or a plane, the surfaces of more than two types are in smooth transition, and specifically, the surfaces can be in transition connection through the arc surface, or the connecting parts of the surfaces of two types are tangent. In this embodiment, the protrusion of the outer surface is a cylindrical protrusion 211, and the end surface and the side surface of the cylindrical protrusion are connected through an arc surface. Specifically, the surface of the protrusion 211 is composed of a cylindrical side surface, a cylindrical end surface, and an arc surface, the cylindrical side surface is a curved surface, the end surface is a plane, and a connection transition portion between the end surface and the cylindrical side surface is an arc surface, please refer to fig. 3. Specifically, the arc-shaped surface includes a circular arc or an irregular arc. That is, the cylindrical protrusion 211, a portion where the end surface of the end far from the inner surface 214 is connected to the side surface, has an arc angle. The cylindrical tail end face and the side face are subjected to chamfering treatment, so that the tail end face of the cylindrical tail end does not have sharp edges and corners but is in an arc-shaped angle, the line contact between the outer surface of the crawler belt and the lawn is avoided, and the lawn is prevented from being torn by the sharp edges and corners. In other embodiments, the protrusion may also be formed into a substantially truncated cone shape, and the end of the truncated cone shape away from the inner surface is connected with the side surface through an arc-shaped surface, so that the end has an arc-shaped angle, and sharp edges are avoided.
In another embodiment, the end of the cylindrical protrusion remote from the inner surface may also be provided with a partial spherical shape. As shown in fig. 4, the boss 212 includes a cylindrical shape 2122 and a partial spherical shape 2121. Preferably, partial sphere 2121 is hemispherical, cylindrical shape 2122 has a distal end that mates with the rounded end of hemispherical shape 2121, and cylindrical shape 2122 and partial sphere 2121 are integrally formed. In other embodiments, the protrusions may be formed in a truncated cone shape with a partial spherical shape at the end of the truncated cone shape, as shown in fig. 5, and the truncated cone shaped protrusion 213 includes a truncated cone shape 2132 and a partial spherical shape 2131. Preferably, the partial sphere 2121 is hemispherical, the end of the truncated cone 2132 fits the circular cross section of the hemispherical sphere 2131, and the cylindrical shape 2122 and the partial sphere 2121 are integrally formed to have an arc-shaped angle to avoid sharp edges and corners.
In another preferred embodiment, the protrusions on the outer surface of the track are part-spherical 214, as shown in FIG. 6, and preferably, the part-spherical 214 is semi-spherical. The contact surface of the caterpillar band and the lawn has no sharp edges and corners, so that damage to the lawn is reduced, and meanwhile, the contact surface of the caterpillar band and the lawn is a plurality of hemispherical surfaces due to the hemispherical structure, so that pressure on the lawn is further dispersed, and damage to the lawn is reduced.
The bulges are uniformly distributed on the outer surface of the crawler belt, gaps for grass to leak are formed between the adjacent bulges, and the grass can leak the gaps between the bulges when the intelligent robot operates and works. Preferably, the joint of the side surface of the cylindrical protrusion and the cross section of the tail end is in arc smooth transition, namely, the tail end of the cylindrical protrusion has an arc angle, and meanwhile, as the side profile of the cylindrical protrusion is in an arc shape, in the process of contacting with the lawn, the contact of the arc side profile to the grass blades of the lawn is all surface contact without any edges and corners, and the grass blades cannot be torn. When the bulges are cylindrical, the outer surface of the crawler belt has a grass combing function on the grassland, so that the damage to the grassland is reduced, and the grass looks more uniform and tidy. Preferably, the protrusions are uniformly distributed, and the pressure of the uniformly distributed protrusions on the grass is also uniformly distributed, so that the pressure is further dispersed.
Preferably, the tooth height L of the protrusions is 10mm-20mm, the protrusions on the outer surface of the crawler directly contact with the lawn to provide driving friction force, and the protrusions enable the contact depth of the protrusions of the crawler and the lawn to be limited to 10mm-20mm, so that the outer surface of the crawler has strong ground holding force, and the climbing and obstacle crossing capabilities of the crawler are considered.
In this embodiment, the front support wheel 203 has a front wheel axle 16, the rear support wheel 201 has a rear wheel axle 18, and the distance between the two wheel axles, i.e., the ground contact length S of the crawler belt, is 200mm to 600mm, i.e., the ground contact length S of the crawler belt is 200mm to 600 mm. For a specific crawler mower, the ground contact length of the crawler is directly related to the climbing capacity of the intelligent robot, when the ground contact length is large, the larger the contact area with the ground is, the larger the friction force can be provided, and meanwhile, if the ground contact length of the crawler is too long, a lot of difficulties are brought to tensioning of the crawler. The utility model discloses set up the ground connection length of track 200mm-600mm and can be guaranteeing track and ground area of contact in order to provide sufficient frictional force, keep the better tensioning effect of track simultaneously.
Since the tracked intelligent robot 100 has a strong climbing ability, if the track 210 can directly contact an object in front of the track, the track can directly run over the object in front, no matter whether the object in front is an obstacle, or a foot, or a pole pile, etc.
Preferably, the intelligent robot 100 includes a track stop 52 at an end of the track 210. The tracked intelligent robot is provided with one track stop 52 at each of the four ends of the track. When an obstacle is present in close proximity to the track, the obstacle first impacts the track stop 52. The intelligent robot 100 also includes an impact sensor for detecting whether an impact event has occurred with the track stop 52. When the track stopper 52 collides with an obstacle, the collision sensor senses the collision event and transmits the detection result to the control module, which controls the intelligent robot 100 to turn or retreat to prevent the track 210 from directly rolling over an object in front of it.
Safety issues are an important consideration for the design and manufacture of intelligent robots. For example, when a common wheeled intelligent robot is in operation, if a child grabs the robot by hand from the outer edge of the machine body for curiosity, the fingers of the child can extend into the bottom of the machine, and if the blade is designed to be too close to the outer edge of the machine body, the fingers of the child can be cut by the blade of the mower, so that danger is caused. International safety regulations require that the distance from the blade to the outer edge of the body be set to be not less than 12cm for a standard wheeled smart robot to protect the safety of the user or touch.
Because the intelligent robot that designs now does not adopt the wheelset to do but has adopted track 210 as the walking equipment, there is the difference in the condition of safety situation itself and the condition of using the wheelset. When the crawler 210 is used as a walking device, the side wall of the crawler frame can prevent a user or other touch persons from extending the hand into the mower to be cut by the rotating blade, so that the safety of the user or the touch persons is greatly guaranteed, and the requirements of international safety regulations are met. Since the blade having no wheel mower safety requirements is no less than 12cm from the outer edge of the body using the crawler 210, the cutting element of the intelligent robot can be set to be less than 10cm from the outer edge of the body.
The outer edge of the fuselage refers to the lateral outermost part of the intelligent robot, and the following situations can be specifically and possibly but not limited to: when the intelligent robot consists of a robot body and an outer floating cover arranged on the robot body, the outer edge of the robot body refers to the edge of the outer floating cover; when the intelligent robot only comprises the body and is not provided with the outer floating cover, the outer edge of the body is the outer edge of the shell; thirdly, when the crawler 210 of the intelligent robot is installed at the outermost side of the body and is in an exposed state, the outer edge of the body refers to the outermost edge of the crawler 210.
Referring to fig. 7, in the embodiment, the width D of the track is set to be 20mm-120mm, and in the case of the same width of the robot body, the cutting element is set closer to the outer edge of the robot body, so that the intelligent robot can obtain a larger cutting range. The intelligent robot can cut more residual lawn area outside the boundary line, thereby further reducing the labor burden of the user in nursing the lawn outside the boundary line.
In this embodiment, a guard 30 is provided at the base of the housing. The guard 30 is located in front of the work module and a protective barrier is constructed in front of the work module to prevent a person's hands or feet from contacting the work module. The guard 30 is connected to the housing base at one end and is free at the other end, forming a barrier having a predetermined height in a vertical direction. For better protection, the free end of the guard 30 is spaced between 40 mm and 70 mm from the ground or work surface.
In addition, the crawler 210 is used as the walking device of the intelligent robot, and compared with the intelligent robot using wheel sets as the walking device, the crawler 210 has a larger contact area with the lawn, so that the pressure of the whole intelligent robot on the lawn surface is greatly reduced, and the damage to the lawn is reduced. In addition, when the wheel set is used as walking equipment, the contact between the wheel set and the lawn surface is point contact, the pressure on the lawn is high, and when the wheel set slips due to insufficient adhesion to the lawn surface, the wheel set can tear the grass on the lawn, so that the lawn is greatly damaged. The supporting surface of the track 210 is cylindrical or hemispherical, the contact area with the ground is large, the friction force is larger, the sliding is not easy to occur, the adhesive force between the track and the ground is increased, and meanwhile, the cylindrical or hemispherical protrusion avoids the contact with the edge angle of the lawn, so that the damage to the lawn is further reduced. Moreover, when the crawler 210 is used as a walking device of the intelligent robot, the mower can have better off-road maneuverability, and the performances of climbing, crossing ditches and the like are better.
It will be appreciated by those skilled in the art that other embodiments of the present invention are possible, as long as the technical spirit of the present invention is the same as or similar to the present invention, or any changes and substitutions based on the present invention are within the scope of the present invention.