CN220536768U

CN220536768U - Material installation equipment and operation vehicle

Info

Publication number: CN220536768U
Application number: CN202321520606.9U
Authority: CN
Inventors: 马东阳; 樊锡鹏; 何江涛
Original assignee: Longi Green Energy Technology Co Ltd
Current assignee: Longi Green Energy Technology Co Ltd
Priority date: 2023-06-14
Filing date: 2023-06-14
Publication date: 2024-02-27
Anticipated expiration: 2033-06-14

Abstract

The embodiment of the utility model provides a material installation device and a working vehicle, wherein the material installation device comprises: the feeding assembly is used for acquiring the materials from the feeding device and carrying the materials; the positioning device is used for positioning the single material from the feeding device before installation; and the installation device is used for installing the materials positioned by the positioning device on a fixed carrier. According to the material mounting equipment provided by the embodiment of the utility model, before the material is mounted, the positioning device can be used for positioning the materials such as the photovoltaic module and the like placed on the bearing piece, so that each material in each batch is positioned at the same position, the accurate consistency of material taking in the subsequent mounting process is ensured, and the mounting precision and the mounting efficiency of the materials in the outdoor mounting process are improved.

Description

Material installation equipment and operation vehicle

Technical Field

The utility model relates to the field of material installation and fixation, in particular to material installation equipment and a working vehicle.

Background

Along with the development and progress of new energy industry, photovoltaic power generation is gradually popularized and used in various different geographic environments.

In the construction of outdoor photovoltaic power plant, in order to reduce the intensity of labour of manpower installation photovoltaic module, industry gradually adopts mechanical equipment such as industrial robot, fork truck, forklift to carry out auxiliary installation when being under construction.

However, since the existing industrial robots are indoor general-purpose devices developed and manufactured for production workshops, the accuracy of the existing industrial robots can meet the use requirements when the existing industrial robots are used in a stable use environment in workshops. However, when it is used for outdoor construction work, it is relatively poor to face outdoor complicated changeable unstable installation environment, causes the product installation accuracy, needs to reposition repeatedly, has greatly reduced installation effectiveness. In addition, there is also a problem of poor mounting accuracy when the construction machine such as a forklift or a forklift is used in an auxiliary manner. Similarly, in the construction industry, the same problems exist for the installation of flat plate-like building materials such as curtain walls, tiles, and the like.

Thus, there is a need to design a mounting apparatus that can improve the accuracy of material mounting in an outdoor environment.

Disclosure of Invention

The utility model provides a material mounting device, a working vehicle and a photovoltaic module mounting method, which are used for solving the problems of poor mounting precision and low efficiency of the existing material during outdoor mounting.

In order to solve the above problems, the present utility model is achieved as follows:

in a first aspect, in an embodiment of the present utility model, there is provided a material mounting apparatus, the mounting apparatus comprising:

the feeding device is used for acquiring the materials and carrying the materials to the positioning device;

the positioning device is used for positioning the single material from the feeding device before installation;

and the installation device is used for installing the materials positioned by the positioning device on a fixed carrier.

Optionally, the material mounting apparatus further comprises:

a feeding device for feeding the material; the feeding device is used for acquiring the materials from the feeding device and carrying the materials to the positioning device.

Optionally, the feeding device comprises:

the feeding frame is provided with a feeding hole for feeding materials at the side part;

the material preparation side frame is arranged at the position of the feeding hole and hinged with the feeding frame, and can rotate to a vertical storage station or a horizontal material preparation station relative to the feeding frame;

The first transmission assembly is fixedly connected with the material preparation side frame so as to receive materials from the outside of the feeding device;

the second transmission assembly is fixedly connected to the bottom of the feeding frame, and the second transmission assembly and the first transmission assembly are used for conveying materials of the horizontal material preparation station into the feeding frame together.

Optionally, along the feeding direction of the feeding hole towards the inside of the feeding frame, the conveying plane of the second conveying assembly is gradually inclined downwards.

Optionally, the inclination angle of the transmission plane of the second transmission assembly is alpha, 0 degrees < alpha is less than or equal to 5 degrees relative to the horizontal plane.

Optionally, the feeding device further comprises:

the first driving assembly is fixedly connected with the feeding frame;

the stop mechanism is fixedly connected with the output end of the first driving assembly;

the first driving assembly drives the stop mechanism to translate along the horizontal direction relative to the feeding frame, and the stop mechanism is intermittently abutted to the surface of the material close to the feeding port.

Optionally, the feeding device further comprises:

the detection device is fixedly connected with the feeding frame or the stop mechanism and is electrically connected with the first driving assembly;

The detection device is used for detecting the position of a material in the feeding frame, which is close to the feeding hole, so as to drive the first driving assembly to drive the stop mechanism to translate.

Optionally, the stop mechanism includes: the swing cylinder is fixedly connected with the output end of the first driving assembly, and when the swing rod of the swing cylinder rotates to be parallel to the surface of the material in the feeding frame, the swing rod intermittently abuts against the surface of the material close to the feeding port; or alternatively, the first and second heat exchangers may be,

the stop mechanism includes: the telescopic cylinder is fixedly connected with the output end of the first driving assembly, and when a piston rod of the telescopic cylinder stretches out to be parallel to the surface of the material in the feeding frame, the piston rod is intermittently abutted to the surface of the material close to the feeding port.

Optionally, the feeding device further comprises:

the discharging support is arranged below the second transmission assembly and is fixedly connected with the feeding frame;

the fixed part of the lifting assembly is fixedly connected with the discharging support;

the output assembly is fixedly connected with the moving part of the lifting assembly and moves up and down along with the moving part of the lifting assembly relative to the discharging support;

The feeding frame is provided with a discharge opening at the side part adjacent to the feeding opening, and the discharging movement direction of the output assembly faces to the discharge opening.

Optionally, the second conveying assembly includes a plurality of conveying rollers arranged in parallel, and the output assembly includes a plurality of conveying belts or conveying chains arranged in parallel;

the conveying belts or the conveying chains are distributed in gaps of the conveying rollers at intervals, and the conveying direction of the conveying belts or the conveying chains is perpendicular to the axis of the conveying rollers.

Optionally, the feeding device further comprises two sets of centering components;

each group of centering components are fixedly connected with the feeding frame, and the two groups of centering components are positioned on two sides of the transmission direction of the second transmission component.

Optionally, each set of said centering components comprises:

the mounting plate is fixedly connected with the feeding frame;

the telescopic cylinder is fixedly connected with the mounting plate;

the guide clamping plate is fixedly connected with the output end of the telescopic cylinder;

each telescopic cylinder drives the corresponding guide clamping plate to move towards the other guide clamping plate in opposite directions.

Optionally, the feeding device further comprises a limiting plate;

the limiting plate is fixed on the side part of the feeding frame, which is opposite to the feeding hole.

Optionally, the positioning device includes:

the positioning support comprises a bearing piece for placing materials;

the positioning components are at least arranged on two opposite sides of the bearing piece, and are used for positioning materials in the bearing piece.

Optionally, the positioning bracket further includes:

the bearing piece is rotationally connected with the fixing seat and can rotate to a folding storage position or an unfolding positioning position relative to the fixing seat;

and the posture adjusting mechanism is used for controlling the carrier to keep a constant inclination angle when the carrier is positioned at the unfolding positioning position.

Optionally, the posture adjustment mechanism is a gas spring;

one end of the gas spring is connected with the bearing piece, and the other end of the gas spring is connected with the fixed seat;

when the gas spring is in a contracted state, the bearing piece rotates to the folding storage position relative to the fixed seat; when the gas spring is in an extension state, the bearing piece rotates to the unfolding positioning position relative to the fixing seat.

Optionally, the mounting device comprises:

a support column;

the fixed part of the first driving mechanism is fixedly connected with the supporting upright post;

one end of the telescopic arm is connected with the moving part of the first driving mechanism, and the first driving mechanism drives the telescopic arm to lift along the vertical direction relative to the supporting upright post;

the picking assembly is connected with the other end of the telescopic arm, and the telescopic arm moves in a telescopic mode to drive the picking assembly to install materials on a fixed carrier.

Optionally, the mounting device further comprises:

and one end of the telescopic arm is connected with the moving part of the first driving mechanism through the angle adjusting mechanism, and the angle adjusting mechanism adjusts the pitching angle of the telescopic arm.

Optionally, the angle adjustment mechanism includes:

the servo motor is fixedly connected with the moving part of the first driving mechanism, and the first driving mechanism drives the servo motor to lift along the vertical direction; the input end of the gear transmission mechanism is connected with the output shaft of the servo motor, and the output end of the gear transmission mechanism is connected with one end of the telescopic arm;

The servo motor drives the telescopic arm to do pitching motion through the gear transmission mechanism.

Optionally, the material mounting apparatus further comprises:

a fixed bottom plate;

the rotary module is characterized in that a fixing piece of the rotary module is fixedly connected with the fixed bottom plate, a moving piece of the rotary module is fixedly connected with the supporting upright post, and the rotary module drives the supporting upright post to rotate relative to the fixed bottom plate.

Optionally, the material mounting apparatus further comprises:

the sliding rail is connected with the fixed bottom plate in a sliding way;

the second driving mechanism is connected to the fixed bottom plate and drives the fixed bottom plate to move along the sliding rail.

Optionally, the pick-up assembly comprises:

a multi-axis rotation mechanism having at least rotational degrees of freedom about three mutually perpendicular axes;

the multi-shaft rotating mechanism is connected between the telescopic arm and the picking tool and is used for driving the picking tool to rotate in different directions;

the position detection device is fixedly connected with the pick-up tool and used for detecting the installation position on the fixed carrier.

Optionally, the position detection means comprises an industrial camera for detecting the mounting position on the stationary carrier by means of visual positioning.

In a second aspect, embodiments of the present utility model also provide a work vehicle for material installation, comprising any of the installation apparatus of the first aspect, the installation apparatus being secured to the work vehicle.

Optionally, the work vehicle further comprises a telescopic shed;

when the shed is in the extended and unfolded state, the shed shields and covers the mounting equipment.

Optionally, the work vehicle further comprises a truck mounted crane mounted on the work vehicle.

According to the material mounting equipment provided by the embodiment of the utility model, before the material is mounted, the positioning device can be used for positioning the materials such as the photovoltaic module and the like placed on the bearing piece, so that each material in each batch is positioned at the same position, the accurate consistency of material taking in the subsequent mounting process is ensured, and the mounting precision and the mounting efficiency of the materials in the outdoor mounting process are improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the description of the embodiments of the present utility model will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 shows a schematic view of a feeding device in a material mounting apparatus according to an embodiment of the present utility model;

FIG. 2 shows a schematic view of a positioning device in a material mounting apparatus according to an embodiment of the present utility model;

FIG. 3 shows a schematic view of a mounting device in a material mounting apparatus according to an embodiment of the present utility model;

FIG. 4 shows a schematic view of a feeder in a material mounting apparatus according to an embodiment of the utility model;

FIG. 5 shows a schematic view of a further feeder in a material mounting apparatus according to an embodiment of the utility model;

FIG. 6 is a schematic view of a side frame of a stock material in a plumb receiving station according to an embodiment of the present utility model;

FIG. 7 is a schematic view of a side frame of a horizontal feed station according to an embodiment of the present utility model;

FIG. 8 shows a schematic view of a feeding device for feeding according to an embodiment of the present utility model;

FIG. 9 shows a schematic view of a feeding device according to an embodiment of the present utility model mounted on a vehicle;

FIG. 10 shows a schematic view of a tilting arrangement of a second transfer assembly in a feeding device according to an embodiment of the present utility model;

FIG. 11 is a schematic view of a first drive assembly and a stop mechanism in a feeder device according to an embodiment of the utility model;

FIG. 12 is a schematic view of a lifting assembly and an output assembly of a feeding device according to an embodiment of the present utility model;

FIG. 13 shows a schematic view of a centering assembly in a feed device according to an embodiment of the utility model;

FIG. 14 is a schematic view of a carrier folded into a stowed position according to an embodiment of the utility model;

FIG. 15 shows a schematic view of a mounting device according to an embodiment of the utility model;

FIG. 16 shows a schematic view of a pickup assembly according to an embodiment of the present utility model;

FIG. 17 is a schematic view showing the mounting device of the embodiment of the present utility model in an operating state;

FIG. 18 is a schematic view showing a mounting device according to an embodiment of the present utility model in a housed state;

fig. 19 shows a schematic view of a work vehicle according to an embodiment of the present utility model.

Reference numerals illustrate:

the device comprises a feeding device-10, a feeding device-20, a positioning device-30, a mounting device-40, a fixed bottom plate-50, a rotary module-60, a sliding rail-70, a second driving mechanism-80, a feeding frame-101, a material preparation side frame-102, a first transmission component-103, a second transmission component-104, a first driving component-105, a stopping mechanism-106, a detection device-107, a discharging support-108, a lifting component-109, an output component-110, a centering component-111, a limiting plate-112, a positioning support-301, a positioning component-302, a supporting column-401, a first driving mechanism-402, a telescopic arm-403, a picking component-404, an angle adjusting mechanism-405, a feeding port-1011, a discharging port-1012, a mounting plate-1111, a telescopic cylinder-1112, a guide clamping plate-1113, a bearing component-3011, a stop-30111, a fixing seat-3012, a posture adjusting mechanism-3013, a multi-axis rotating mechanism-4041, a picking tool-4042, a position detecting device-4043, a servo motor-4051, a gear transmission mechanism-4052.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be appreciated that reference throughout this specification to "one embodiment" or "an embodiment" means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present utility model. Thus, the appearances of the phrases "in one embodiment" or "in an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

Referring to fig. 1 to 3, an embodiment of the present utility model provides a material mounting apparatus including:

the feeding device 20 is used for acquiring and carrying the materials from the feeding device 10;

The positioning device 30 is used for positioning the single materials from the feeding device 20 before installation;

and a mounting means 40 for mounting the plate-like member positioned by the positioning means 30 on a fixed carrier 40.

As shown in fig. 1 to 3, the material installation apparatus according to the embodiment of the present utility model is an automatic installation apparatus for materials in a production vehicle or an outdoor construction site, and the installed materials may be block-shaped or sheet-shaped building materials, for example, common ceramic tiles, glass curtain walls or photovoltaic modules. The material mounting apparatus may specifically include a loading device 20, a positioning device 30, and a mounting device 40. The loading device 20 can take material and carry it for subsequent installation. In the material installation device according to the embodiment of the present utility model, the material installation device further includes a positioning device 30, and before the material is installed, the feeding device 20 first places the obtained material on the positioning device 30, and positions each material one by one through the positioning device 30. After the positioning of the material is completed, the material is removed from the positioning device 30 using the mounting device 40 and then mounted and secured to the stationary carrier.

Illustratively, when the above-described material mounting apparatus is used for mounting plate-like members such as photovoltaic modules, after a truck conveys the packaged photovoltaic modules to an outdoor construction site, workers remove the photovoltaic modules one by one after the workers unpack the photovoltaic modules, and then carry the photovoltaic modules to the positioning device 30. Before the photovoltaic module is installed, the positioning device 30 can position each photovoltaic module one by one, so that each material in each batch can be positioned at the same position, and the accurate consistency of material taking in the subsequent installation process is ensured. Finally, the positioned photovoltaic modules are mounted on the outdoor photovoltaic support one by the mounting device 40. In order to clearly and intuitively describe the material installation device in the embodiment of the present application, the following embodiments will also use the installation process of the photovoltaic module as an example. Similarly, the same advantages are obtained when such panel-like member mounting apparatus is used for mounting tile or curtain wall other building material products, and the description thereof will not be repeated here.

This kind of material erection equipment of this application embodiment, before the material installation, can be fixed a position to the platy member such as photovoltaic module of placing on the carrier by positioner for each material of each batch all is in the same position, ensures the accurate uniformity that follow-up installation procedure got the material, helps improving the material and installs the precision and improve installation effectiveness when outdoor installation.

Optionally, referring to fig. 1 to 4, the material mounting apparatus further includes:

a feeding device 10, wherein the feeding device 10 is used for supplying the materials; the loading device 20 is used for taking the material from the feeding device 10 and carrying the material to the positioning device 30.

Specifically, as shown in fig. 4, the material installation apparatus according to the embodiment of the present application may further include the feeding device 10 in addition to the feeding device 20, the positioning device 30 and the installation device 40. The feeder device 10 may be used to supply material delivered to a job site by a truck from a storage site to the installation. The feeder 20 may take material from the feeder 10 and handle it for subsequent installation.

Illustratively, when the above-mentioned material mounting apparatus is used for mounting plate-like members such as photovoltaic modules, after a truck conveys the packaged photovoltaic modules to an outdoor construction site, a worker unpacks the photovoltaic modules, places the stacked photovoltaic modules on the feeding device 10, and then the feeding device 20 cooperates with the feeding device 10, and the feeding device 20 takes out the photovoltaic modules from the feeding device 10 one by one, and then conveys the photovoltaic modules to the positioning device 30. The feeding device 10 can realize automatic transmission supply of materials to other devices, and is beneficial to improving the efficiency of material supply.

Alternatively, referring to fig. 5 to 9, the feeding device 10 includes:

a feeding frame 101, wherein a feeding port 1011 for feeding materials is arranged at the side part of the feeding frame 101;

a material preparation side frame 102, wherein the material preparation side frame 102 is arranged at the position of the feeding port 1011, the material preparation side frame 102 is hinged with the feeding frame 101, and the material preparation side frame 102 can rotate to a vertical storage station or a horizontal material preparation station relative to the feeding frame 101;

the first conveying assembly 103 is fixedly connected with the material preparation side frame 102 so as to receive materials from the outside of the feeding device 10;

the second conveying assembly 104, the second conveying assembly 104 is fixedly connected to the bottom of the feeding frame 101, and the second conveying assembly 104 and the first conveying assembly 103 together convey the materials of the horizontal material preparation station into the feeding frame 101.

As illustrated in fig. 5 to 9, the feeding device 10 of the embodiment of the present application includes a feeding frame 101 and a stock side frame 102 located at one side of the feeding frame 101. The feeding frame 101 may be a cubic frame structure formed by welding metal profiles or bolting and fixing, the side surface of the feeding frame 101 is provided with a railing for a photovoltaic module to enter, any side surface of the railing is provided with a feed port 1011 for the photovoltaic module to enter, and the feed port 1011 can be formed on the left side of the feeding frame 101, namely, three sides around the feeding frame 101 form a continuous fence, the left side surface is disconnected without the fence, and the photovoltaic module can enter the feeding frame 101 through the feed port 1011.

As shown in fig. 1 and 5, a stock side frame 102 is further connected to the position of the inlet 1011, and the stock side frame 102 and the loading frame 101 may be a planar frame structure made of the same material, and the stock side frame 102 may have the same shape as the inlet 1011 and a rectangular shape as shown. One side edge of the material preparation side frame 102 is hinged at a position, close to the bottom, of the feeding frame 101, and the material preparation side frame 102 can rotate relative to the feeding frame 101 to be at a vertical storage station shown in fig. 6, and the material preparation side frame 102 can also rotate relative to the feeding frame 101 to be at a horizontal material preparation station shown in fig. 7. In order to keep the stock side frame 102 in a horizontal posture after being turned open, an angle limiting structure may be provided on the stock side frame 102 or the feeding frame 101, and the maximum turning angle of the stock side frame 102 may be limited to 90 degrees by the angle limiting structure. Or a telescopic hydraulic pull rod is connected between the feeding frame 101 and the stock side frame 102, and the stock side frame 102 is prevented from rotating excessively by the pulling action of the hydraulic pull rod. In addition, a gear transmission mechanism can be installed on the feeding frame 101, and the motor is used for driving the gear transmission mechanism to realize automatic opening and closing of the material preparation side frame 102 and also play a role in angle limiting.

As shown schematically in fig. 6 and 7, a first conveying assembly 103 is fixed on the stock side frame 102, and the first conveying assembly 103 can move independently relative to the stock side frame 102 and can be lifted up to be in the position of fig. 6 or put down to be in the position of fig. 7 along with rotation of the stock side frame 102. A second transmission assembly 104 is fixed at the bottom of the feeding frame 101, the second transmission assembly 104 can independently move relative to the feeding frame 101, and the first transmission assembly 103 and the second transmission assembly 104 are driven to operate structurally independently from each other.

Referring to fig. 7, when the material preparation side frame 102 rotates relative to the feeding frame 101 and is at the horizontal material preparation station, the photovoltaic modules placed in the material yard can be carried and placed on the first transmission module 103 of the material preparation side frame 102 by using a forklift or a robot, and then the first transmission module 103 and the second transmission module 104 run simultaneously, the photovoltaic modules on the material preparation side frame 102 can be transmitted into the feeding frame 101 through the feeding port 1011, and after the photovoltaic modules are transmitted into the feeding frame 101, the photovoltaic modules in the feeding frame 101 can be grabbed and installed by the robot one by one for use, and meanwhile, the idle material preparation side frame 102 can continuously receive the forklift or the robot to carry and place the next group of photovoltaic modules. It can be appreciated that when the feeding device 10 of the embodiment of the present application is used for feeding a photovoltaic module, the consumption rate of the photovoltaic module in the feeding frame 101 can be controlled, so that when the photovoltaic module in the feeding frame 101 is about to be consumed, a new photovoltaic module is placed on the material preparation side frame 102, and then the new photovoltaic module is transmitted into the empty feeding frame 101 through the first transmission module 103 and the second transmission module 104, so that the continuity of the feeding of the photovoltaic module is ensured. Fig. 9 also shows a schematic diagram of the installation of the feeding device 10 on a vehicle with a truck crane in combination with an actual feeding installation scenario, and a lifting mechanism on the vehicle can be used for lifting the photovoltaic module from the feeding frame 101.

In addition, it should be noted that, whether the first conveying assembly 103 or the second conveying assembly 104 may have the same or different structures, and may be a conveying assembly formed by arranging a plurality of conveying rollers in parallel, or may be a conveying assembly formed by a conveying belt and a belt wheel, and the specific structural form of the conveying assembly is not limited in this embodiment of the present application.

According to the feeding device 10 of the embodiment, when material is required to be fed, the material preparing side frame 102 can be rotated to be opened to the horizontal material preparing station, once the material in the material preparing frame 101 is consumed, the material temporarily stored in the material preparing side frame 102 can be immediately transferred into the material preparing frame 101, and then the material preparing side frame 102 can continuously receive a new set of temporarily stored material. After the material supply is finished, the material preparation side frame 102 can be turned and closed to the plumb receiving station, at this time, the material preparation side frame 102 is tightly attached to the side surface of the material loading frame 101, and the occupied space is smaller. Therefore, the feeding device can improve the continuity of material supply by designing the material preparation side frame 102 which can be retracted and released to form a buffer material preparation area in front of the feeding opening 10 of the feeding frame 101, thereby being beneficial to improving the material supply efficiency and the site construction efficiency.

Alternatively, referring to fig. 7 and 10, the conveying plane of the second conveying assembly 104 is gradually inclined downward along the feeding direction X of the feeding port 1011 toward the inside of the feeding frame 101.

In particular, in one embodiment, for a sheet-like or plate-like material product, such as a plurality of photovoltaic modules stacked and leaning together, the second conveying module 104 at the bottom of the feeding frame 101 may be obliquely arranged in order to avoid the photovoltaic modules from tilting due to shaking or shaking during feeding and taking materials. As shown in fig. 7 and 10, the conveying plane of the second conveying member 104 is gradually inclined downward in the feeding direction X of the inside of the feeding frame 101 toward the feeding port 1011. For example, when the second transfer assembly 104 is a plurality of transfer rolls, the transfer plane is a common tangent to each transfer roll. When the second transfer assembly 104 is a transfer belt, the transfer plane is the belt surface of the transfer belt. Therefore, after the photovoltaic module is transmitted into the feeding frame 101, the photovoltaic module automatically leans right on the fence of the feeding frame 1 due to the action of the inclination of the transmission plane, so that the feeding is more stable and is not easy to fall and damage.

Alternatively, referring to FIG. 10, the inclination angle of the transport plane of the second transport assembly 104 with respect to the horizontal is α,0 ° < α+.ltoreq.5°.

Specifically, in one embodiment, in order to avoid damage caused by rapid dive impact of the photovoltaic module due to the excessively large inclination angle of the second transmission module 104, therefore, as illustrated in fig. 10, the inclination angle α of the transmission plane of the second transmission module 104 with respect to the horizontal plane is not more than 5 ° at the maximum, and may be designed to be 0.5 °, 1 °, 2 °, 3 °, 4 ° or 5 ° according to the space size in the feeding frame 101, so that a gentle slope may be formed in the feeding frame 101.

Optionally, referring to fig. 8, the feeding device 10 further includes:

the first driving assembly 105, wherein the first driving assembly 105 is fixedly connected with the feeding frame 101;

the stop mechanism 106, the stop mechanism 106 is fixedly connected with the output end of the first driving component 105;

the first driving assembly 105 drives the stop mechanism 106 to translate along the horizontal direction relative to the feeding frame 101, and the stop mechanism 106 intermittently abuts against the surface of the material near the feeding port 1011.

In particular, in one embodiment, for sheet-like or plate-like material products of a plurality of photovoltaic modules stacked together, as consumption of the photovoltaic modules decreases, the photovoltaic modules may be damaged by tilting from the side toward the feed port 1011. Thus, as illustrated in fig. 8, the feeding device 10 of the present embodiment may further comprise a first drive assembly 105 and a stop mechanism 106. The first driving component 105 is fixedly arranged on the feeding frame 101, and the stop mechanism 106 is fixedly arranged on the output end of the first driving component 105. When the first driving component 105 acts, the stop mechanism 106 can be driven to reciprocate in the X direction schematically shown in fig. 8. Along the X direction of the drawing, a plurality of photovoltaic modules are stacked together. When the thickness of the stacked plurality of photovoltaic modules is reduced, the stop mechanism 106 can move along with the first driving assembly 105 to adapt to the reduction of the thickness of the plurality of photovoltaic modules.

In the feeding process, the stop mechanism 106 can move towards one side of the material preparation side frame 102 under the drive of the first driving assembly 105, or the stop mechanism 106 acts to avoid a photovoltaic module close to the feeding port 1010 in the plurality of photovoltaic modules, so that an external installation device or a robot is convenient to take out the photovoltaic modules from the feeding frame 101. In the gap between the external installation device or the robot material taking installation, the stop mechanism 106 can move towards one side far away from the material preparation side frame 102 under the drive of the first driving component 105, or the stop mechanism 106 is in self-action protruding contact with the surface of the photovoltaic component close to the feed inlet 10. The stopper mechanism 106 intermittently abuts the surface of the photovoltaic module near the feed port 10. It should be noted that, the first driving assembly 105 may be a mature servo driving linear module, or may be replaced by another driving assembly such as a motor and a synchronous belt, and the motion form output by the first driving assembly 105 may be linear motion.

Therefore, in the embodiment of the application, one side of a plurality of photovoltaic modules stacked together in the feeding frame 101 is supported on the fence of the feeding frame 101, the other side of the photovoltaic modules can be blocked by the stop mechanism 106, and the stop mechanism 106 is intermittently abutted with the photovoltaic modules, so that the normal feeding installation is not hindered while the photovoltaic modules are prevented from toppling over.

Optionally, referring to fig. 11, the feeding device 10 further includes:

the detection device 107, the detection device 107 is fixedly connected with the feeding frame 101 or the stop mechanism 106, and the detection device 107 is electrically connected with the first driving assembly 105;

the detecting device 107 is configured to detect a material position in the feeding frame 101 near the feeding port 1011, so as to drive the first driving component 105 to drive the stop mechanism 106 to translate.

Specifically, in one embodiment, the detecting device 107 may also be fixed on the feeding frame 101 or the stopper mechanism 106, while the detecting device 107 is electrically connected to the first driving assembly 105. When the detecting device 107 is fixed with the feeding frame 101, the distance between the detecting device 107 and the surface of the photovoltaic module close to the feeding port 1011 can be detected in a non-contact manner to judge where the photovoltaic module located at the outermost side is located, so that the first driving module 107 is triggered to drive the stop mechanism 106 to translate so as to block the photovoltaic module, and toppling is prevented. As shown in fig. 11, when the detecting device 107 is fixed to the stopping mechanism 106, the detecting device 107 and the stopping mechanism 106 can move along with the first driving component 105 at the same time, and when the detecting device 107 and the stopping mechanism 106 contact the photovoltaic component near the feeding hole 1011 at the same time, the first driving component 105 can be triggered to stop acting, and the photovoltaic component is blocked by the stopping mechanism 106 to prevent toppling. In connection with the above description, it is easily understood that the detecting device 107 may be a non-contact distance sensor such as a photoelectric sensor, or an industrial camera capable of determining a distance through an image, and the detecting device 107 may be a mechanical travel switch or a capacitive detecting switch. For specific types, principles and usage of the various detection devices 107, reference may be made to corresponding product manuals, which are not described in detail in this embodiment.

Through using detection device 107 in feedway in this application embodiment, can acquire the position that is in the photovoltaic module of outside in the material loading frame 101 accurately to drive backstop mechanism 106 motion to this position and block it, prevent that control of empting is more accurate swift.

Optionally, the stop mechanism 106 includes: the swing cylinder is fixedly connected with the output end of the first driving assembly 105, and when the swing rod of the swing cylinder rotates to be parallel to the surface of the material in the feeding frame 101, the swing rod intermittently abuts against the surface of the material close to the feeding port 1011; or alternatively, the first and second heat exchangers may be,

the stopper mechanism 106 includes: the telescopic cylinder is fixedly connected with the output end of the first driving assembly 105, and when a piston rod of the telescopic cylinder extends out to be parallel to the surface of the material in the feeding frame 101, the piston rod intermittently abuts against the surface of the material close to the feeding port 1011.

Specifically, in one embodiment, the swing cylinder may be used as the stop mechanism 106, where the cylinder body of the swing cylinder is fixedly connected to the output end of the first driving component 105, the swing cylinder may be driven by the first driving component 105 to reciprocate along the X direction illustrated in fig. 8, the swing rod of the swing cylinder may swing to be at 0 degrees or 90 degrees, and when the swing rod is at one of the 0 degrees and 90 degrees according to the installation direction of the swing cylinder, the swing rod may abut against the photovoltaic component of the feeding port 1011 when parallel to the surface of the photovoltaic component in the feeding frame 101, and may avoid the photovoltaic component when at the other position. Fig. 11 shows an illustration of the swing lever in the 0 degree position, where both the feed and take out installations of the photovoltaic module are unobstructed. When the swing rod rotates 90 degrees along the arrow direction P shown in FIG. 11, the swing rod can be abutted against the photovoltaic module of the feed port 1011 to prevent toppling.

Similar to the above-mentioned oscillating cylinder, a telescopic cylinder belt may be used instead of the oscillating cylinder, and in this case, the cylinder body of the telescopic cylinder is fixedly connected to the output end of the first driving assembly 105, and the telescopic cylinder may be driven by the first driving assembly 105 to move along the X direction illustrated in fig. 8. During installation, the piston rod of the telescopic cylinder is arranged in parallel with the photovoltaic module in the feeding frame 101, and when the piston rod of the telescopic cylinder is in a retracted state, feeding and taking installation of the photovoltaic module are not hindered. When the piston rod of the telescopic cylinder stretches out, the telescopic cylinder can be abutted against the surface of the photovoltaic module close to the feed inlet 1011, so that toppling is prevented.

Optionally, referring to fig. 8 and 12, the feeding device 10 further includes:

the unloading support 108 is arranged below the second transmission assembly 104, and the unloading support 108 is fixedly connected with the feeding frame 101;

the lifting assembly 109, the fixed part of the lifting assembly 109 is fixedly connected with the unloading support 108;

the output assembly 110, the moving part of the lifting assembly 109 is fixedly connected with the output assembly 110, and the output assembly 110 moves up and down along with the moving part of the lifting assembly 109 relative to the discharge support 108;

Wherein, a discharge port 1012 is provided on the side of the feeding frame 101 adjacent to the feeding port 1011, and the discharging movement direction of the output assembly 110 faces the discharge port 1012.

In particular, in one embodiment, as schematically shown in fig. 8 and 12, the feeding device of the present embodiment may further include a discharge support 108, a lifting assembly 109, and an output assembly 110. The discharge support 108 may be a frame structure having the same shape and size as the bottom of the loading frame 101, and the discharge support 108 may include four rectangular legs and a cross member connected between the adjacent legs. The discharge support 108 is integrally installed below the second transmission assembly 104 and fixedly connected with the feeding frame 101. The fixing piece of the lifting assembly 109 can be fastened on the cross beam of the unloading support 108 through bolts, and the moving piece of the lifting assembly 109 is fixedly connected with the output assembly 110. When the lifting assembly 109 is actuated, the output assembly 110 can be driven to move up and down along the Z direction illustrated in fig. 8 and 12.

Also, the side surface of the feeding frame 101 is further provided with a discharge port 1012, and the discharge port 1012 and the feed port 1011 are located on different sides, as shown in fig. 5 and 8, and the discharge port 1012 may be located on a side surface adjacent to the feed port 1011. When the lifting assembly 109 lifts the output assembly 110 to a position higher than the top of the second conveying assembly 104, the output assembly 110 can lift the tray carrying the photovoltaic assembly in the feeding frame 101, so that the tray is separated from the second conveying assembly 104. Since the discharge movement of the output assembly 110 is directed toward the discharge port 1012, the output assembly 110 can deliver the tray from the discharge port 1012. Therefore, the feeding device 10 of the embodiment of the application also has the function of automatically discharging the empty tray, and the discharging of the empty tray does not affect the feeding action, so that the consistency of automatic feeding and tray discharging can be realized, and the feeding efficiency is higher.

Alternatively, referring to fig. 6 and 12, the second conveying assembly 104 includes a plurality of conveying rollers arranged in parallel, and the output assembly 110 includes a plurality of conveying belts or chains arranged in parallel;

Specifically, in one embodiment, as shown in fig. 6, in the feeding device 10 of the embodiment, when the second conveying assembly 104 includes a plurality of conveying rollers arranged in parallel, a gap for the output assembly 110 to pass through during lifting is reserved between adjacent conveying rollers, at this time, the selected output assembly 110 may include a plurality of conveying belts or conveying chains arranged in parallel, and in combination with the illustration of fig. 12, four conveying chains are taken as an example, and four conveying chains are spaced from each other, and each conveying chain is located in the gap between two conveying rollers at a corresponding position when viewed from a top view of the feeding device, and the conveying direction of the conveying chain is perpendicular to the axis of the conveying rollers. Referring to fig. 8, after the output unit 110 is lifted up by the lifting unit 109, the tray is sent out from the Y direction shown in fig. 8 after the conveyor chain starts to drive.

The conveying belt or the conveying chain is embedded in the gap of the conveying roller, so that the equipment volume of the feeding device can be effectively reduced, and the device is more suitable for outdoor mobile operation.

Optionally, referring to fig. 6, the feeding device 10 further comprises two sets of centering assemblies 111;

each group of centering components 111 is fixedly connected with the feeding frame 101, and two groups of centering components 111 are positioned at two sides of the transmission direction of the second transmission component 104.

Specifically, in one embodiment, as shown in fig. 6, in the feeding device 10 in this embodiment, two sets of centering assemblies 111 are further fixed on the feeding frame 101, where the two sets of centering assemblies 111 are disposed opposite to each other, and are located at two sides of the conveying direction of the second conveying assembly 104. The centering assembly 111 can perform centering and positioning on the photovoltaic assembly in the feeding frame 101 through reciprocating telescopic motion along the Y direction shown in fig. 6. When the photovoltaic modules are transmitted on the second transmission module 104, the centering modules 111 on two sides can clamp and center the photovoltaic modules from two sides, so that each batch of photovoltaic modules are positioned at the same position, are placed neatly, and are convenient for accurate grabbing and installation in the next step.

Alternatively, referring to fig. 6 and 13, each set of centering assemblies 111 includes:

The mounting plate 1111, the mounting plate 1111 is fixedly connected with the feeding frame 101;

a telescopic cylinder 1112, wherein the telescopic cylinder 1112 is fixedly connected with the mounting plate 1111;

a guide clamping plate 1113, wherein the guide clamping plate 1113 is fixedly connected with the output end of the telescopic cylinder 1112;

each of the telescopic cylinders 1112 drives the corresponding one of the guide clamp plates 1113 toward the other one of the guide clamp plates 1113 toward each other.

Specifically, in one embodiment, fig. 13 illustrates a structure of a centering assembly 111 according to an example of the present application, where the centering assembly 111 includes a mounting plate 1111, a telescopic cylinder 1112, and a guide clamping plate 1113. The mounting plate 1111 can be provided with a through hole for a piston rod of the telescopic cylinder 1112 to pass through, one side of the mounting plate 1111 is fixed with the telescopic cylinder 1112, the piston rod of the telescopic cylinder 1112 passes through the through hole and extends to the other side of the mounting plate 1111, and the piston rod of the telescopic cylinder 1112 is fixed with a guide clamping plate 1113. As shown in fig. 13, two telescopic cylinders 1112 may be arranged at intervals along the length direction of the mounting plate 1111, so that the two telescopic cylinders 1112 are more stable when driving the guide clamping plate 1113.

In combination with the illustration of fig. 6, the two sets of centering components 111 are disposed opposite to each other, and accordingly, the two guide clamping plates 1113 are disposed face to face, and when the piston rod of each telescopic cylinder 1112 extends, one guide clamping plate 1113 is driven to move toward the other guide clamping plate 1113, and the distance between the two guide clamping plates 1113 is reduced, so that the photovoltaic components stacked on the tray can be centered by pushing and adjusting the position of the tray.

Optionally, referring to fig. 6, the feeding device 10 further includes a limiting plate 112;

the limiting plate 112 is fixed on the side of the feeding frame 101 opposite to the feeding port 1011.

Specifically, in one embodiment, as shown in fig. 6, besides performing position adjustment centering in the Y direction by using two sets of centering components 111, a limiting plate 112 may be mounted and fixed on a side portion of the feeding frame 101 opposite to the feeding port 1011, where the limiting plate 112 may be the same as the width of the feeding port 1011, and mounted and fixed at the end of the feeding direction, and after the photovoltaic component enters the feeding frame 101, the photovoltaic component is blocked and limited by the limiting plate 112 after contacting the limiting plate 112, so that the photovoltaic component can accurately stay at a position blocked by the limiting plate 112 in the X direction, and the stay position of each batch of photovoltaic components in the X direction can be ensured to be the same.

Optionally, referring to fig. 3, the positioning device 30 includes:

a positioning bracket 301, wherein the positioning bracket 301 comprises a bearing piece 3011 for placing materials;

the positioning components 302 are arranged at least on two opposite sides of the bearing piece 3011, and the positioning components 302 are used for positioning materials in the bearing piece 3011.

Specifically, as illustrated in fig. 3, the positioning device 30 of the embodiment of the present application includes a positioning bracket 301 and a positioning assembly 302. The positioning bracket 301 includes a carrier 3011 for placing a photovoltaic module. The bearing piece 3011 can be a hollow frame structure or a flat plate-shaped supporting plate, and can support and bear the photovoltaic module. The positioning components 302 are at least disposed on two opposite sides of the carrier 3011, and the positioning components 302 may be fixed on a frame around the carrier 3011.

As illustrated in fig. 3, the carrier 3011 is a rectangular pallet, the M direction is the length direction of the carrier 3011, the N direction is the width direction of the carrier 3011, and two opposite sides along the M direction are respectively connected with a positioning assembly 302. A block 3012 can be installed and fixed at a position of the bearing 3011 close to the ground, and the block 3012 can prevent the photovoltaic module from sliding down along the bearing surface of the bearing 3011. It will be readily appreciated that the stop 3012 could also be replaced by a short frame at the bottom of the carrier 3011. When the length of the carrier 3011 is long, two or more positioning assemblies 302 may also be mounted and fixed at intervals in the long-side position, as illustrated in fig. 3. When the photovoltaic module is placed on the carrier 3011, the photovoltaic module can be embedded in the carrying space of the tray, and then the positioning modules 302 on two sides start to work and move towards the middle, so that the photovoltaic module can be pushed to move to a preset position, for example, the center line of the short side of the photovoltaic module coincides with the center line of the short side of the carrier 3011 to realize centering. In addition, the photovoltaic module can be pushed to move to a position close to the side edge of any side to realize side positioning. It should be noted that, the positioning assembly 302 has a part capable of moving telescopically, and the positioning assembly 302 may not be limited to a conventional cylinder or other linear movement module. Therefore, the positioning assembly 302 installed on the bearing piece 3011 can be used for positioning the photovoltaic assemblies supplied by transmission, so that each photovoltaic assembly in each batch is located at the same position, and the photovoltaic assemblies are placed neatly, so that the photovoltaic assemblies can be accurately grasped and installed in the next step.

Optionally, referring to fig. 3 and 14, the positioning bracket 301 further includes:

the fixing base 3012, the bearing piece 3011 is rotatably connected with the fixing base 3012, and the bearing piece 3011 can rotate to a folding storage position or an unfolding positioning position relative to the fixing base 3012;

and a posture adjustment mechanism 3013 for controlling the carrier 3011 to maintain a constant inclination angle when in the deployed positioning position.

Specifically, as illustrated in fig. 3 and 14, the positioning bracket 301 further includes a fixing base 3012 and an attitude adjusting mechanism 3013. A rotating shaft support with a hinge hole is arranged on one of the bearing 3011 and the fixed base 3012, a rotating shaft is fixed on the other of the bearing 3011 and the fixed base 3012, and the bearing 3011 and the fixed base 3012 can be connected in a rotating way by utilizing the cooperation of the rotating shaft and the hinge hole.

Fig. 3 is a schematic diagram illustrating the carrier 3011 rotating to a deployed positioning position relative to the fixed base 3012, where the carrier 3011 is in an inclined posture relative to the ground, and the inclined carrier 3011 can stably support and carry the photovoltaic module, and the positioning module 302 will start to perform positioning. Fig. 14 is a schematic view of the carrier 3011 rotating to a folded storage position relative to the fixed base 3012, where the carrier 3011 is in a vertical posture relative to the ground, so that the projection in the horizontal plane is small, the occupied space is small, and the storage is easy.

In order to realize the adjustment of the posture of the carrier 3011 to realize the position switching, a posture adjustment mechanism 3013 is further included in the positioning bracket 301, the posture adjustment mechanism 3013 is connected to at least one of the carrier 3011 and the fixed base 3012, when the posture adjustment mechanism 3013 acts, the carrier 3011 can be controlled to rotate to the deployed positioning position in the arrow direction illustrated in fig. 3, and under the mechanical connection limitation of the posture adjustment mechanism 3013, the carrier 3011 can maintain a constant inclination angle, for example, the carrier 3011 can maintain an inclination posture of 60 degrees with the ground. It will be readily appreciated that the attitude adjustment mechanism 3013 can also control the carrier 3011 to rotate in the opposite direction after the material is mounted, so as to bring the carrier 3011 back to the folded storage position illustrated in fig. 14.

In connection with the above, it will be appreciated that the posture adjustment mechanism 3013 used in the embodiments of the present application may be provided to power the rotation of the carrier 3011, may not be limited to a telescopic rod having an automatic telescopic function, or may be a rope, a chain mechanism, or a gear transmission mechanism driven by a motor, etc. that is wound up and unwound.

Therefore, in the embodiment of the application, by using the posture adjustment mechanism 3013 to drive the carrier 3011 to rotate to be in the folded storage position or the unfolded positioning position, the switching of different states of the carrier 3011 can be realized, and the installation function of the photovoltaic module and the storage convenience of the device are considered.

Alternatively, referring to fig. 3 and 14, the posture adjustment mechanism 3013 is a gas spring;

one end of the gas spring is connected with the bearing piece 3011, and the other end of the gas spring is connected with the fixing seat 3012;

when the gas spring is in a contracted state, the bearing piece 3011 rotates to the folding storage position relative to the fixed seat 3012; when the gas spring is in an extension state, the bearing piece 3011 rotates to the unfolding positioning position relative to the fixing base 3012.

Specifically, as shown in fig. 3 and 14, in one embodiment, the posture adjustment mechanism 3013 may be a gas spring driven by compressed gas. One end of the gas spring is connected with the bearing piece 3011, and the other end of the gas spring is connected with the fixed seat 3012. For example, the upper end of the gas spring is hinged to the carrier 3011, the lower end of the gas spring is hinged to the fixed base 3012, and when the expansion and contraction of the gas spring change, the gas spring itself also rotates around the hinge point of the lower end and the fixed base 3012. When the button of the air spring is pressed to make the air spring pop up and stretch, the air spring rotates along the arrow direction shown in fig. 3 at the same time, so that the bearing piece 3011 can be pushed to rotate around the fixed seat 3012 to the unfolding positioning position, when the air spring is compressed to make the air spring in the shrinkage state, the air spring rotates along the arrow direction opposite to the arrow direction shown in fig. 3 at the same time, and at the same time, the air spring can pull the bearing piece 3011 to rotate around the fixed seat 3012 to the folding storage position. The posture adjusting mechanism 3013 adopting the gas spring as the driving carrier 3011 rotates has simple structure and does not need extra energy consumption.

Alternatively, referring to fig. 15 and 16, the mounting device 40 includes:

a support column 401;

a first driving mechanism 402, wherein a fixing portion of the first driving mechanism 402 is fixedly connected with the support column 401;

the telescopic arm 403, one end of the telescopic arm 403 is connected with the moving part of the first driving mechanism 402, and the first driving mechanism 402 drives the telescopic arm to lift in the vertical direction relative to the support column 401;

the picking assembly 404, the picking assembly 404 is connected with the other end of the telescopic arm 403, and the telescopic arm 403 moves in a telescopic way to drive the picking assembly 404 to mount the material on the fixed carrier.

In particular, as illustrated in fig. 15 and 16, in one implementation, the mounting device 40 of the present embodiment may include a support post 401, a first drive mechanism 402, a telescoping arm 403, and a pickup assembly 404. The support column 401 is a support component of the installation device 40, and may include a bottom plate parallel to a horizontal plane and a vertical plate welded to the bottom plate vertically, where a right angle part between the vertical plate and the bottom plate may be welded with a triangular rib plate for reinforcement and fixation. The first driving mechanism 402 is a linear motion module, the moving part of the first driving mechanism 402 can move linearly relative to the fixing part, and the fixing part of the first driving mechanism 402 can be fixedly connected with the support column 401 through bolts and corresponding clamps. It is to be understood that the first driving mechanism 402 may be a mature servo driving linear module, or may be replaced by other driving components such as a motor and a synchronous belt. One end of the telescopic arm 403 may be fixedly connected to the moving part of the first driving mechanism 402 by a bolt and a corresponding connection. When the first driving mechanism 402 acts, the telescopic arm 403 can be driven to lift along the vertical direction Z illustrated in fig. 15 relative to the support column 401, so that the mounting device 40 can realize that the pickup assembly 404 moves to different height positions, and, because the pickup assembly 404 is connected to the other end of the telescopic arm 403, the pickup assembly 404 can be driven to be in different far and near positions by the telescopic movement of the telescopic arm 403. Referring to fig. 15, the telescopic arm 403 in the embodiment of the present application is a telescopic mechanism formed by sequentially sliding and connecting three arm sections, and the power of the telescopic mechanism can be provided by a cylinder or a screw slider mechanism fixed on the telescopic arm 403.

The installation device 40 of the embodiment of the application not only can drive the pickup assembly 404 to move to different height positions, but also can realize the far and near position adjustment of the pickup assembly 404 through the extension and contraction of the extension arm 403, so that the movable range of the pickup assembly 404 is wider, and the installation and construction requirements of more rows of photovoltaic assemblies can be met.

Optionally, referring to fig. 15 and 16, the mounting device 40 further includes:

and an angle adjusting mechanism 405, wherein one end of the telescopic arm 403 is connected with the moving part of the first driving mechanism 402 through the angle adjusting mechanism 405, and the angle adjusting mechanism 405 adjusts the pitching angle of the telescopic arm 403.

Specifically, as illustrated in fig. 15 and 16, in one embodiment, the mounting device 40 of the present embodiment further includes an angle adjustment mechanism 405, and the angle adjustment mechanism 405 is disposed between the telescopic arm 403 and the first driving mechanism 402. One end of the telescopic arm 403 is connected to the moving part of the first driving mechanism 402 via an angle adjusting mechanism 405. Therefore, when the first driving mechanism 402 starts to work, the angle adjusting mechanism 405 and the telescopic arm 403 can be driven to move up and down along the Z direction, and meanwhile, when the angle adjusting mechanism 405 starts to work, the telescopic arm 403 can be driven to swing in a pitching mode to change the pitching angle, so that the requirements of different installation dip angles of the photovoltaic module are met. In the installation device 40 of the embodiment of the present application, the angle adjusting mechanism 405 may be a telescopic rod with a variable length, where one end of the telescopic rod is hinged to the first driving mechanism 402, and the other end of the telescopic rod is hinged to the moving portion of the first driving mechanism 402, and when the telescopic rod stretches and contracts, the telescopic arm 403 can be driven to perform pitching motion. Alternatively, the angle adjusting mechanism 405 may drive the telescopic arm 403 to move in a pitching motion by means of gear transmission.

Alternatively, referring to fig. 15 and 16, the angle adjustment mechanism 405 includes:

the servo motor 4051 is fixedly connected with the moving part of the first driving mechanism 402, and the first driving mechanism 402 drives the servo motor 4051 to lift in the vertical direction;

the input end of the gear transmission mechanism 4052 is connected with the output shaft of the servo motor 4051, and the output end of the gear transmission mechanism 4052 is connected with one end of the telescopic arm 403;

the servo motor 4051 drives the telescopic arm 403 to perform pitching motion through the gear transmission mechanism 4052.

In particular, as illustrated in fig. 15 and 16, in one implementation, the angular adjustment mechanism 405 of the present embodiments may be implemented using a combination of a motor and a gear set. Specifically including a servo motor 4051 and a gear train 4052. The housing of the servo motor 4051 may be fastened to the moving part of the first driving mechanism 402 by a screw, and the servo motor 4051 may move up and down in the Z direction along with the moving part of the first driving mechanism 402. An input end of the gear transmission 4052 is connected to an output shaft of the servo motor 4051, and an output end of the gear transmission 4052 is connected to one end of the telescopic arm 403. When the servo motor 3051 receives the driving signal to start rotating, the torque can be transmitted to the telescopic arm 403 through the gear transmission mechanism 4052, so that the telescopic arm 403 can pitch and swing. It will be readily appreciated that the gear assembly 4052 comprises at least one drive gear fixed to the output shaft of the servo motor 4051 and a driven gear fixed to the end of the telescopic arm 403, the drive gear being in mesh with the driven gear and the driven gear also being hinged to the moving part of the first drive mechanism 402. The angle adjusting mechanism 405 for realizing pitching and swinging by utilizing the motor and the gear transmission mechanism has small volume, small occupied space and more flexible installation and arrangement.

Optionally, referring to fig. 15 and 16, the material mounting apparatus further includes:

a fixed bottom plate 50;

the rotary module 60, the mounting of rotary module 60 with fixed bottom plate 50 fixed connection, the moving part of rotary module 60 with support post 401 fixed connection, rotary module 60 drives support post 401 is relative fixed bottom plate 50 rotates.

Specifically, as illustrated in fig. 15 and 16, in one embodiment, the material installation apparatus of the embodiment of the present application further includes a fixed base plate 50 and a swing module 60. The swing module 60 includes a moving member and a fixed member that are rotatable relative to each other. The fixed part of the rotary module 60 is fixedly connected with the fixed bottom plate 50, and the moving part of the rotary module 60 is fixedly connected with the supporting upright 401. When the rotary module 60 receives the driving signal from the controller, the moving member rotates relative to the fixed member, so as to drive the support column 401 to rotate relative to the fixed base plate 50. Thus, by using the rotary module 60 mounted at the bottom of the support column 401, a degree of freedom of rotation about the Z axis can be increased for the pickup assembly 404, the range of motion of the pickup assembly 404 can be enlarged, and flexibility thereof can be improved.

A slide rail 70, wherein the slide rail 70 is slidably connected with the fixed bottom plate 50;

and a second driving mechanism 80, wherein the second driving mechanism 80 is connected to the fixed bottom plate 50, and the second driving mechanism 80 drives the fixed bottom plate 50 to move along the sliding rail 70.

Specifically, as illustrated in fig. 15 and 16, in one embodiment, the material mounting apparatus of the present embodiment further includes a slide rail 70 and a second drive mechanism 80. The slide rail 70 is disposed below the fixed base plate 50 and slidably connected. For example, a slide groove or a slider is provided at a position on the fixed base plate 50 corresponding to the slide rail 70. The second driving mechanism 80 is connected to the fixed bottom plate 50, and the second driving mechanism 80 drives the fixed bottom plate 50 to move along the sliding rail 70. The second drive mechanism 80 may be, for example, a gear motor and a gear, with a rack disposed between two parallel slide rails 70, the gear meshing with the rack. When the gear motor operates to drive the gear to roll on the gear, the fixed bottom plate 50 and other components on the fixed bottom plate 50 can be driven to move along the sliding rail 70. Of course, the second driving mechanism 80 may also be in the form of a synchronous belt mechanism driven by a motor, and the embodiment of the present application will not be described in detail.

It will be seen that such a material mounting apparatus allows for parallel movement of the pick-up assembly 404 in the horizontal direction X. With reference to the illustrations of fig. 17 and 18, it is easy to understand that when the vehicle carrying the material mounting apparatus is stationary at a certain construction position, the second driving mechanism 80 may drive the pickup assembly 404 to translate to implement the mounting of the multi-row photovoltaic modules, without frequently moving the vehicle position, so as to reduce the complexity of the mounting operation and improve the mounting efficiency.

Optionally, referring to fig. 16, the pickup assembly 404 includes:

a multi-axis rotation mechanism 4041, said multi-axis rotation mechanism 4041 having at least rotational degrees of freedom about three mutually perpendicular axes;

a pick-up tool 4042, wherein the multi-axis rotation mechanism 4041 is connected between the telescopic arm 403 and the pick-up tool 4042, and the multi-axis rotation mechanism 4042 is used for driving the pick-up tool 4042 to rotate in different directions;

the position detection device 4043 is fixedly connected with the pick-up tool 4042, and is used for detecting the installation position on the fixed carrier.

Specifically, as illustrated in fig. 16, in one implementation, the pick-up assembly 404 of the present embodiment may include a multi-axis rotation mechanism 4041, a pick-up tool 4042, and a position detection device 4043. The multi-axis rotation mechanism 4041 may be a driving module with three degrees of freedom of rotation including at least three servo motors, the driving module may be mounted and fixed at the end of the telescopic arm 403, the output end of the driving module may be connected with the pickup tool 4042, and when the multi-axis rotation mechanism 4041 receives the action of the control signal, the pickup tool 4042 may be driven to rotate around three axes of rotation of the servo motors in space, so as to flexibly pick up the photovoltaic module to be mounted. The pick-up tool 4042 can be a frame structure made of metal profiles through fixed connection, and a plurality of pneumatic sucking discs are installed on one plane of the frame structure and can be used for sucking photovoltaic modules. In addition, a position detecting device 4043 is also mounted and fixed on the pick-up tool 4042. After the picking tool 4042 absorbs the photovoltaic module, when the photovoltaic module is placed on the fixed carrier, meanwhile, the position detection device 4043 can be used for identifying and judging whether the picking tool 4042 moves to a proper installation position, and when the position is inaccurate, the multi-axis rotation mechanism 4041 can drive the picking tool 4042 to move for fine adjustment, so that the photovoltaic module is accurately aligned with the position to be installed. The position detecting device 4043 used in the embodiment of the present application may be a mechanical contact switch or a non-contact photoelectric device.

Optionally, the position detection means 4043 comprises an industrial camera for detecting the mounting position on the stationary carrier by means of visual positioning.

Specifically, in one implementation, the position detection device 4043 of an embodiment of the present application may include an industrial camera. An industrial camera can be used to capture images of the underside of the motion area of the pick-up tooling 4042 and the profile of the fixed carrier can be identified using an image recognition algorithm to determine if the mounting location is reached. The non-contact type position detection mode reduces collision risk and has higher detection efficiency.

Referring to fig. 19, an embodiment of the present application further provides a work vehicle for material installation, including any of the aforementioned installation apparatus, secured to the work vehicle.

As illustrated in fig. 19, embodiments of the present application also provide a work vehicle for material installation that includes any of the aforementioned installation apparatus. The installation apparatus is secured to a work vehicle that can carry the installation apparatus to various construction sites in different ground conditions. For example, a work vehicle having tires as running gear may be applied to paved road sites, and a work vehicle having crawler tracks as running gear may be applied to non-paved road sites.

Optionally, the work vehicle further comprises a telescopic shed;

Specifically, in one embodiment, the work vehicle of the present application may further include a telescopic shed, where the telescopic shed includes a telescopic and foldable support frame, and a soft waterproof cloth is fixed on the support frame. The support framework is connected to the vehicle body and can slide and stretch relative to the vehicle body, when the support framework stretches out and expands, the waterproof cloth can completely shield the installation equipment, and the fault of equipment operation caused by sand and dust in the outdoor environment is prevented. When the material installation operation is needed, the supporting framework is contracted and folded.

Specifically, in one embodiment, the working vehicle of the embodiment of the present application may further include a truck crane integrated with the working vehicle, where the truck crane may be convenient for hoisting the stacked materials from the ground to the feeding device 10 in groups, and may also be convenient for dismounting and maintaining the mounting device on the vehicle.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The embodiments of the present utility model have been described above with reference to the accompanying drawings, but the present utility model is not limited to the above-described embodiments, which are merely illustrative and not restrictive, and many forms may be made by those having ordinary skill in the art without departing from the spirit of the present utility model and the scope of the claims, which are to be protected by the present utility model.

Claims

1. A material mounting apparatus, the material mounting apparatus comprising:

the feeding device is used for acquiring materials and carrying the materials to the positioning device;

2. The material mounting apparatus of claim 1, wherein the material mounting apparatus further comprises:

3. The material mounting apparatus of claim 2, wherein the feed device comprises:

4. A material mounting apparatus according to claim 3, wherein the conveying plane of the second conveying assembly is gradually inclined downwards in the feeding direction of the feed opening towards the interior of the feeding frame.

5. The material mounting apparatus of claim 4, wherein the inclination angle of the transport plane of the second transport assembly with respect to the horizontal is α,0 ° < α+.ltoreq.5°.

6. A material mounting apparatus according to claim 3, wherein the feed device further comprises:

the first driving assembly is fixedly connected with the feeding frame;

7. The material mounting apparatus of claim 6, wherein the feed device further comprises:

8. A material mounting apparatus according to claim 3, wherein the feed device further comprises:

9. The material mounting apparatus of claim 8, wherein the second conveyor assembly comprises a plurality of side-by-side conveyor rollers and the output assembly comprises a plurality of side-by-side conveyor belts or chains;

10. A material mounting apparatus as claimed in claim 3 wherein the feeder means further comprises two sets of centering assemblies;

11. The material mounting apparatus of claim 1, wherein the positioning device comprises:

the positioning support comprises a bearing piece for placing materials;

12. The material mounting apparatus of claim 11, wherein the positioning bracket further comprises:

13. The material mounting apparatus of claim 1, wherein the mounting device comprises:

a support column;

14. The material mounting apparatus of claim 13, wherein the mounting device further comprises:

15. The material mounting apparatus of claim 14, wherein the angle adjustment mechanism comprises:

16. The material mounting apparatus of claim 13, wherein the pick-up assembly comprises:

17. A work vehicle for material installation, comprising a material installation apparatus as claimed in any one of claims 1 to 16, the material installation apparatus being secured to the work vehicle.

18. The work vehicle of claim 17, wherein said work vehicle further comprises a telescoping shed;

19. The work vehicle of claim 17, further comprising a truck mounted crane mounted to the work vehicle.