CN210126909U - Vacuum suction device for logistics objects - Google Patents

Abstract

The application provides a vacuum suction device of logistics objects. This vacuum suction device includes: a support; the sponge suckers are detachably arranged on different positions of the bracket; the air path air distribution assembly is used for being connected with a negative pressure main air path, and the negative pressure main air path is respectively communicated with the sponge suction tools through a plurality of air pipes, so that negative pressure is provided for the sponge suction tools to adsorb logistics objects.

Description

Vacuum suction device for logistics objects

Technical Field

The application relates to the field of warehouse logistics, in particular to a vacuum suction device for logistics objects.

Background

In the fields of warehousing, logistics and the like, operations such as carrying, placing, unstacking, stacking and the like of various goods or logistics objects are needed, and the boxes of different goods or logistics objects are various in types and different in size and shape.

In the whole process of the warehouse and logistics industry from the traditional to the automatic and intelligent evolution, automatic goods warehousing, goods carrying and parcel delivery are realized by using automatic equipment such as robots, and the like, so that the labor is replaced by manual repeated labor, and the method is an important direction for reducing the cost and improving the efficiency in the field of warehouse and logistics.

The sponge suction tool and the vacuum chuck assembly are universal adsorption devices, are suitable for adsorbing and conveying surfaces made of various materials, such as cartons, packaging bags, boards without being planed, metal plates and the like, and are widely applied to automatic conveying, hoisting and other equipment.

However, most of the existing suction tools or suction cups are designed according to a specific box size, and cannot be adapted to a wide variety of box sizes and even different box shapes in the field of warehouse logistics. In addition, in the process of unstacking, when a large suction tool sucks a small box, in order to avoid sucking a nearby box body, the suction must be started from the stack type edge, so that the unstacking efficiency is low, and the flexibility is poor.

SUMMERY OF THE UTILITY MODEL

The application provides a vacuum suction device of logistics objects.

According to a first aspect of the present application, there is provided a vacuum suction device for a logistics object, comprising:

a support;

the sponge suckers are detachably arranged on different positions of the bracket;

the air path air distribution assembly is used for being connected with a negative pressure main air path, and the negative pressure main air path is respectively communicated with the sponge suction tools through a plurality of air pipes, so that negative pressure is provided for the sponge suction tools to adsorb logistics objects.

According to one embodiment, the stent comprises:

a stent body having a predetermined shape;

the sponge suction device comprises a support body, a plurality of suction device connecting pieces and a plurality of sponge suction devices, wherein the plurality of suction device connecting pieces are respectively provided with a clamping groove structure matched with the shape of the support body and are sleeved on the support body, each suction device connecting piece can slide along the support body and is fixed at a preset position on the support body through screws, and the plurality of sponge suction devices are respectively fixedly connected with the suction device connecting pieces.

According to one embodiment, the apparatus further comprises a weighing assembly fixedly mounted on top of the support frame and comprising:

the weighing part is used for measuring the weight of the logistics object adsorbed by the sponge suction tool;

and the limiting part is used for limiting the movement range of the weighing part.

According to one embodiment, the weighing section comprises:

the weighing lower connecting column is fixedly arranged on the bracket;

the weighing sensor is positioned above the weighing lower connecting column, and the lower end of the weighing sensor is connected to the weighing lower connecting column;

and the weighing upper connecting column is positioned above the weighing sensor and is connected with the upper end of the weighing sensor.

According to one embodiment, the stopper portion includes:

the hollow lower limiting column is fixedly arranged on the bracket, and the upper end of the hollow lower limiting column is provided with a hole;

go up the spacing post, go up the lower extreme of spacing post and extend to in the hole of spacing post upper end under the hollow, and with the cooperation of spacing post formation shaft hole under the hollow, go up the spacing post and have the boss in the bottom, the size of boss is greater than the size of the hole of spacing post upper end under the hollow.

According to one embodiment, the weighing assembly comprises a plurality of weighing parts and a plurality of limiting parts which are evenly distributed.

According to one embodiment, the load cell is a tension and compression cell.

According to one embodiment, the device further comprises a driver connector, wherein the lower portion of the driver connector is fixedly connected with the weighing upper connecting column and the upper limiting column, and the upper portion of the driver connector is fixedly connected with a driver for driving the device.

According to one embodiment, the device further comprises an inertial measurement unit mounted on said holder and/or said sponge absorber.

According to one embodiment, the apparatus further comprises a chuck assembly, said chuck assembly comprising:

the vacuum sucker is communicated with the gas path gas distribution assembly through a gas pipe;

and the sucker mounting rack is used for fixedly mounting the vacuum sucker to the bracket.

According to one embodiment, each of said sponge suckers and each of said vacuum cups is provided with a non-return valve.

According to one embodiment, the gas path and gas distribution assembly comprises:

a body having a cavity;

the main air path joint is connected to the negative pressure main air path and communicated with the cavity of the body;

the sponge air path joints are respectively connected to the sponge suckers and are communicated with the cavity of the body;

and the at least one sucker air path joint is respectively connected to the at least one vacuum sucker and is communicated with the cavity of the body.

According to one embodiment, the main gas line connection has a rotatable inner bearing and the connection plane of the main gas line connection to the body is sealed by a vacuum O-ring.

According to one embodiment, the gas circuit and gas distribution assembly further comprises a first vacuum gauge to monitor the gas pressure within the cavity of the body.

According to one embodiment, the gas path gas distribution assembly further comprises a first fixed connecting piece, the first fixed connecting piece is provided with a first groove-shaped hole and a second groove-shaped hole, the first fixed connecting piece is fixedly installed on the support through the first groove-shaped hole by a screw, and the body of the gas path gas distribution assembly is fixedly installed on the first fixed connecting piece through the second groove-shaped hole by a screw.

According to one embodiment, the apparatus further comprises a shunt control valve located on the gas path from the gas path gas distribution assembly to the sponge suction tool and the vacuum chuck, the shunt control valve comprising:

the second vacuum meter is used for monitoring the air pressure on the air path;

and the vacuum valve is used for controlling the on-off of the gas path.

According to one embodiment, the apparatus further comprises an impact detection assembly comprising:

the second fixed connecting piece is fixedly connected to a preset position on the bracket through a screw;

the guide post extends along the vertical direction and penetrates through the through hole in the second fixed connecting piece;

the collision block is fixedly connected to the bottom of the guide pillar;

a guide post connecting piece, which is provided with a horizontal part extending horizontally and a vertical part extending downwards from the horizontal part, wherein the horizontal part is fixedly connected with the upper part of the guide post;

the travel switch is provided with a body, a roller and a rotary swing rod, the body is fixedly connected to the second fixed connecting piece, the roller is rotatably connected to the body through the rotary swing rod, and the roller abuts against the guide pillar connecting sheet and is excessively abutted against the vertical part from the horizontal part abutted against the guide pillar connecting sheet along with the rising of the guide pillar connecting sheet.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the application. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

FIG. 1 shows a schematic view of a vacuum suction device of a logistics object according to one embodiment of the present application;

FIG. 2 shows a cross-sectional view of the vacuum suction apparatus along the length of the sponge suction tool;

FIG. 3 shows a cross-sectional view of the holder, weighing assembly and drive connection of the vacuum chuck assembly in the direction A of FIG. 1;

FIG. 4 illustrates a perspective view of a chuck assembly according to one embodiment of the present application;

FIG. 5 illustrates a perspective view of an air channel distribution assembly according to one embodiment of the present application;

FIG. 6 illustrates a perspective view of a collision detection assembly according to one embodiment of the present application.

Detailed Description

Embodiments of the present application are described in detail below with reference to the accompanying drawings. It should be noted that the following description is merely exemplary in nature and is not intended to limit the present application. Further, in the following description, the same reference numbers will be used to refer to the same or like parts in different drawings. The different features in the different embodiments described below can be combined with each other to form further embodiments within the scope of the application.

Fig. 1 shows a schematic view of a vacuum suction device of a logistics object according to an embodiment of the present application. As shown in FIG. 1, the device 100 may include a frame 110, a plurality of sponge suckers 120, and an air path and distribution assembly 130. The bracket 110 may extend in a horizontal direction and may have a predetermined shape for carrying other components of the apparatus 100 according to the actual situation in operation. A plurality of sponge suckers 120 are detachably mounted on the holder 110 at different positions. Four sponge suckers 120 are shown in fig. 1, but it will be understood by those skilled in the art that the number of sponge suckers can be selected according to actual needs, and since the sponge suckers 120 are detachably mounted on the rack 110, the proper mounting position on the rack 110 can be selected according to the stacking condition or desired stacking condition of goods or logistics objects to mount each sponge sucker for convenient operation. Those skilled in the art will also understand that an appropriate standard sponge suction module can be selected as the sponge suction device in the device 100 of the present application according to actual needs. The air path air distribution assembly 130 is used for connecting a negative pressure main air path (not shown in fig. 1). The air path air distribution assembly 130 may be connected to a plurality of air pipes (not shown in fig. 1), and the negative pressure main air path is respectively communicated with the plurality of sponge suckers 120 through the air pipes, so as to provide negative pressure to the plurality of sponge suckers 120 to adsorb the logistics objects. When the negative pressure main gas circuit is opened, vacuum is formed in the sponge suction tool, and the sponge suction tool can adsorb the logistics objects when contacting the surfaces of the logistics objects; when the negative pressure main air passage is closed or the sponge suction tool is disconnected from the negative pressure main air passage, the sponge suction tool gradually loses the vacuum condition, so that the logistics objects are released. However, if the sealing performance is good, the change of the vacuum degree in the sponge suction device may be slow, and at this time, the gas can be blown reversely into the sponge suction device to accelerate the release speed. From this, can be according to waiting to operate conditions such as size and shape and the locating place of commodity circulation object and install a plurality of sponge suction tools on the suitable position of the support of vacuum suction tool device to make the device can adapt to different types of box, the flexibility is strong, and a plurality of sponge suction tools can also once carry a plurality of commodity circulation objects simultaneously in addition, thereby improved operating efficiency greatly.

Figure 2 shows a cross-sectional view of the vacuum suction device along the length of the sponge suction device. Referring to fig. 1, the length direction of the sponge suction tool is the direction a in fig. 1. As shown in fig. 1 and 2, the supporter 110 may include a supporter body 111 and a plurality of suction tool connection members 112. The holder body 111 may have a predetermined shape, for example, it may be a standard profile, having a structure in the form of a rail. The suction tool connecting member 112 is a member for fixing the sponge suction tool 120 to the holder body 111, and may have a catching groove structure (e.g., a C-shaped structure as shown in fig. 2) that matches the shape of the holder body 111, so as to be able to be fitted over the holder body 111. The sleeving mode can improve the connection reliability between the sponge suction tool and the support, and the structure is adopted to bear the force, rather than a screw to bear the load. Each of the suction tool connection members 112 can slide along the holder body 111, and after the suction tool connection member 112 slides to a desired position, it can be fixed to the holder body 111 by a screw. Each sponge suction tool 120 can be fixedly connected with the corresponding suction tool connecting member 112 by riveting, screwing, welding, and the like. Through the connection mode, the position of the sponge suction tool 120 on the support body 111 can be flexibly adjusted, so that the specification of different logistics objects to be carried is adapted.

Fig. 3 shows a cross-sectional view of the holder, the weighing assembly and the drive connection of the vacuum chuck arrangement in the direction a in fig. 1. As shown in fig. 1 and 3, the vacuum suction device 100 may further include a weighing assembly 140. The weighing assembly 140 is fixedly installed on the top of the bracket 110, and may include a weighing part and a limiting part. The weighing part and the stopper part of the weighing module 140 will be described in detail below.

The weighing part of the weighing unit 140 may be used to measure the weight of the object of logistics adsorbed by the sponge sucker 120, and may include a weighing lower connecting column 141, a weighing sensor 142 and a weighing upper connecting column 143. As shown in fig. 3, the weighing lower connecting column 141 is fixedly mounted on the bracket 110, for example, directly fixedly mounted on the bracket body 111 by screws. The load cell 142 is positioned above the load lower post 141, and the lower end of the load cell 142 is connected to the load lower post 141, for example, by a mounting screw of the load cell 142. The load attachment post 143 is positioned above the load cell 142 and is connected to the upper end of the load cell 142, for example, by mounting screws of the load cell 142. In addition, the weigh bridge 143 may be screwed to the actuator linkage 150 (as will be described in detail below). The load cell 142 may be a tension/compression cell capable of measuring tension and compression forces in the axial direction of the cell. Therefore, when the sponge sucker 120 adsorbs the logistics objects, the weighing sensor 142 generates a pulling force through the bracket 110 and the weighing lower connecting column 141, so that the weighing sensor 142 can know the weight of the logistics objects adsorbed by the sponge sucker 120 by measuring the pulling force. From this, can learn the weight of commodity circulation object in the commodity circulation object handling to reduce the independent weighing process of commodity circulation object, improved efficiency and reduced independent weighing equipment's input.

The restraint portion of the weighing assembly 140 may be used to limit the range of motion of the weighing portion, which may include a hollow lower restraint post 144 and an upper restraint post 145. As shown in fig. 3, a hollow lower restraint post 144 is fixedly mounted to the bracket 110, for example, by screws. The lower hollow restraining post 144 has a cavity therein to receive the lower end of the upper restraining post 145 and an aperture at the upper end of the lower hollow restraining post 144 so that the lower end of the upper restraining post 145 extends into the aperture at the upper end of the lower hollow restraining post 144 and forms an axial hole fit with the lower hollow restraining post 144. The shaft holes of the upper and lower limiting columns 145 and 144 cooperate to prevent the load cell 142 from receiving excessive lateral force, so as to achieve the limiting effect in the horizontal direction. The upper retention post 145 has a boss at the bottom end that is larger in size than the hole in the upper end of the hollow lower retention post 144. In addition, the upper limit post 145 may be screw-coupled to the driver connector 150 (described in detail below). Therefore, the size of the boss at the bottom end of the upper limiting post 145 and the hole at the top end of the lower limiting post 144 can enhance the reliability of the connection between the driver connector 150 and the bracket 110, so as to achieve the limiting effect in the vertical direction. When the connection between the weighing sensor 142 and the weighing lower connecting column 141 and/or the weighing upper connecting column 143 is loosened, the boss at the bottom end of the upper limiting column 145 abuts against the top of the lower limiting column 144 inside the hollow lower limiting column 144 to realize longitudinal force bearing, so that the bracket 110 cannot fall off or fall off from the driver connecting piece 150.

As shown in fig. 1 and 3, the weighing module 140 may include a plurality of weighing parts and a plurality of position-limiting parts that are uniformly distributed, so that the reliability of weighing and connection may be improved. As shown in fig. 1, the weighing assembly 140 includes four weighing parts and four limiting parts, which are uniformly distributed.

From this, the subassembly of weighing can realize that vacuum suction tool device can weigh adsorbed commodity circulation object when adsorbing and removing commodity circulation object to operating efficiency has been improved. According to one embodiment, the vacuum chuck apparatus 100 may further include an inertial measurement unit (not shown) that may be mounted on the support 110 and/or the sponge chuck 120. Therefore, the inertia measurement unit can provide the attitude information and the acceleration information of the sponge suction tool, so that dynamic weighing can be performed.

As described above, the vacuum chuck device 100 can further include the driver connector 150. As shown in fig. 1 and 3, a lower portion of the driver connector 150 is fixedly connected (e.g., fixedly connected by screws) to the weighing upper connecting column 143 and the upper limiting column 145, and an upper portion of the driver connector 150 is adapted to be fixedly connected to a driver (e.g., a robot arm, etc.) for driving the vacuum chuck apparatus 100. Thus, automated equipment such as robots, robotic arms, etc. may be connected to and control the movement of the entire vacuum chuck apparatus 100 through the drive connections 150. According to one embodiment, the driver connector 150 may have a hollow structure to accommodate an air path between a sponge suction tool and/or a vacuum chuck (described below) and an air path distribution assembly.

FIG. 4 illustrates a perspective view of a chuck assembly according to one embodiment of the present application. As shown in fig. 1 and 4, the vacuum suction device 100 may further include a suction cup assembly 160, and the suction cup assembly 160 may include at least one vacuum suction cup 161 and a suction cup mounting bracket 162. The vacuum chuck 161 is connected to the gas distribution assembly 130 through a gas pipe (not shown), so that a negative pressure can be obtained by the gas distribution assembly to adsorb the material flow. Two vacuum cups 161 are shown in fig. 4, but it will be understood by those skilled in the art that the number and arrangement of the vacuum cups can be selected according to actual needs, so as to adapt to the size, box type or placement of the objects to be adsorbed. Vacuum chuck 161 may be fixedly mounted to support frame 110 by chuck mount 162. For example, the vacuum chuck 161 and the chuck mounting bracket 162 and the support 110 may be connected by screws. Therefore, the vacuum suction device 100 is provided with the sponge suction device and the vacuum sucker, so that the matching use of the sponge suction device and the vacuum sucker can adapt to the requirements of adsorption and moving and carrying of different box-shaped logistics objects, and the whole device is higher in adaptability and flexibility. As shown in figure 1, the size of the vacuum chuck is smaller than that of a sponge suction tool, so that the vacuum chuck is more suitable for adsorbing smaller logistics objects, is flexible and convenient, and has good adaptability to small logistics objects.

According to an embodiment of the present application, a check valve (not shown in the drawings) may be provided in each sponge sucker and each vacuum chuck of the vacuum sucker device. The check valve can ensure that any sponge suction tool and vacuum sucker can be automatically locked when not adsorbing the logistics objects, thereby ensuring the vacuum degree of the suction tool device.

FIG. 5 illustrates a perspective view of an air channel distribution assembly according to one embodiment of the present application. As shown in fig. 1 and 5, the air path distribution assembly 130 may include a body 131, a main air path connector 132, a plurality of sponge air path connectors 133, and at least one suction cup air path connector 134. A cavity is provided in the body 131. The main air path joint 132 may be connected to a negative pressure main air path (not shown) providing negative pressure through a pipe, and the main air path joint 132 communicates with the cavity of the body 131. Each sponge air path connector 133 may be connected to the sponge suction tool 120 through a pipe and communicate with the cavity of the body 131. Therefore, the sponge suction tool 120 can obtain the negative pressure from the negative pressure main air passage through the communication relationship among the pipeline, the sponge air passage joint 133, the cavity of the body 131, and the main air passage joint 132, so as to be used for adsorbing the logistics objects. The suction cup air fitting 134 may be connected to the vacuum suction cup 161 by a tube and communicate with the cavity of the body 131. Accordingly, the vacuum chuck 161 can obtain a negative pressure from the negative pressure main air passage for adsorbing the material flow object through the communicating relationship among the pipe, the chuck air passage joint 134, the cavity of the body 131, and the main air passage joint 132.

The main air passage joint 132 may have a rotatable internal bearing (not shown) so that when it is connected to the negative pressure main air passage, the joint portion may rotate to prevent the torsional bending of the air tube beyond a minimum bend radius during operation of the vacuum chuck apparatus 100 from breaking or leaking. The main air passage joint 132 and the body 131 may be connected by screwing, etc., and the connection plane of the main air passage joint 132 and the body 131 may be sealed by a vacuum O-ring 135 to prevent air leakage.

The air path distribution assembly 130 may also include a first vacuum gauge 136 to monitor the air pressure within the cavity of the body 131. In addition, the air path distribution assembly 130 may further include a first fixed connector 137. As shown in fig. 5, the first fixing link 137 may have a first groove-shaped hole 137A and a second groove-shaped hole 137B, the first fixing link 137 may be fixedly mounted to the bracket 110 by a screw through the first groove-shaped hole 137A, and the body 131 of the air path distribution assembly 130 may be fixedly mounted to the first fixing link 137 by a screw through the second groove-shaped hole 137B. Thus, the air path distribution assembly 130 can be fixed on the bracket 110 of the vacuum suction device 100. Because the screws are fixedly installed through the groove-shaped holes, the horizontal installation position and the vertical installation height of the air path air distribution assembly are adjustable.

Referring again to fig. 1 and 2, the vacuum chuck device 100 may further include a shunt control valve 170. The shunt control valve 170 may be located on the pneumatic path from the pneumatic path distributing assembly 130 to the sponge suction 120 and the vacuum chuck 161, and may include a second vacuum gauge 171 and a vacuum valve 172. The second vacuum gauge 171 may be used to monitor the air pressure on the air path, and the vacuum valve 172 may be used to control the on/off of the air path. Therefore, the sponge suction devices and the vacuum suction cups can be respectively controlled to be connected with and disconnected from the negative pressure main air path by controlling the vacuum valves 172, so that the adsorption and release of the logistics objects can be controlled.

FIG. 6 illustrates a perspective view of a collision detection assembly according to one embodiment of the present application. As shown in fig. 1 and 6, the vacuum suction device 100 may further include a collision detecting assembly 180. The impact detection assembly 180 may include a second fixed link 181, a guide post 182, an impact mass 183, a guide post attachment tab 184, and a travel switch 185. The second fixing connector 181 may be fixedly connected to a predetermined position on the bracket 110 by a screw. For example, a screw may fixedly connect the second fixing link 181 to the bracket 110 through the vertical portion thereof. In addition, a through hole can be formed in the horizontal portion of the second fixed connecting member 181, the guide post 182 can extend in the vertical direction and pass through the through hole in the second fixed connecting member 181 to form a shaft hole fit, and the fit between the guide post 182 and the shaft hole of the through hole in the second fixed connecting member 181 ensures that the guide post 182 and the guide post connecting piece 184 can only perform one-dimensional movement in the vertical direction without rotating or translating in the horizontal direction. An impact mass 183 for contacting the adsorbed material flow object is fixedly attached to the bottom of the guide pillar 182. It will be understood by those skilled in the art that the mounting position of the second fixed link 181 on the bracket 110 and the length of the guide post 182 may be appropriately selected for the purpose of collision detection. For example, by appropriately selecting the installation position of the second fixed link 181 and the length of the guide post 182 so that the impact block 183 is slightly lower than the bottoms of the sponge suction tool 120 and the vacuum chuck 161, when the logistic object comes into contact or collides with the impact block 183, an early warning signal can be issued to indicate that the logistic object is about to come into contact with the suction tool.

The guide post attachment piece 184 has a horizontal portion 184A extending horizontally and a vertical portion 184B extending downwardly from the horizontal portion 184A. The upper portion of the guide post 182 may be fixedly coupled to the horizontal portion 184A of the guide post attachment tab 184 by a screw. According to one embodiment, the collision detecting assembly 180 may include two guide posts 182, as shown in FIG. 6. Therefore, the upper portions of both guide posts 182 are fixedly connected to the horizontal portion 184A of the guide post coupling piece 184, so that the guide post coupling piece 184 does not rotate.

In the initial position (i.e., when there is no collision with the physical distribution object), the guide post 182 is at its lowermost position, and the lower end of the vertical portion 184B of the guide post attaching piece 184 fixedly connected to the guide post 182 abuts against the horizontal portion of the second fixed link 181, so that the guide post 182 and the collision block 183 do not fall. The travel switch 185 includes a body 185A, a roller 185B, and a rotary swing lever 185C. The body 185A of the travel switch 185 is fixedly coupled to the second fixed connector 181 (e.g., by threading, welding, riveting, or the like as appropriate). The roller 185B may be rotatably connected to the body 185A by rotating the swing lever 185C. In the initial position (i.e., when there is no collision with the object of logistics), the roller 185B abuts against the guide post coupling tab 184. When the impact block 183, the guide post 182, and the guide post connecting piece 184 are raised together with the contact of the adsorbed material object with the impact block 183, the roller 185B is also raised by abutting against the horizontal portion 184A of the guide post connecting piece 184, thereby driving the rotary swing link 185C to rotate about the connecting shaft between the rotary swing link 185C and the body 185A. When the rotation angle of the rotary swing link 185C exceeds a preset stroke, the stroke switch 185 is triggered to send a signal indicating that the physical distribution object has collided with the collision detecting unit. If the impact block 183, the guide post 182 and the guide post connecting piece 184 continue to rise together, the roller 185B will transition from the horizontal portion 184A abutting against the guide post connecting piece 184 to the vertical portion 184B abutting against the guide post connecting piece 184, and the rotation angle of the rotary swing link 185C will not increase any more so as to avoid exceeding the working range of the travel switch 185. Thereby, whether contact and collision with the object of the material flow to be adsorbed occur can be detected by the collision detecting component, so that the driving component can control the next operation.

According to one embodiment, the travel switch 185 may be a long life travel switch. Since the vacuum suction apparatus may need to frequently suck the physical distribution object, it is more advantageous to select a long-life stroke switch as the collision detecting device.

Although the above description includes many specific arrangements and parameters, it should be noted that these specific arrangements and parameters are merely illustrative of one embodiment of the present application. This should not be taken as limiting the scope of the application. Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the application. Accordingly, the scope of the application should be construed based on the claims.

Claims (17)

1. A vacuum suction device for a logistics object is characterized by comprising:

a support;

the sponge suckers are detachably arranged on different positions of the bracket;

the air path air distribution assembly is used for being connected with a negative pressure main air path, and the negative pressure main air path is respectively communicated with the sponge suction tools through a plurality of air pipes, so that negative pressure is provided for the sponge suction tools to adsorb logistics objects.

2. The vacuum chuck device for physical distribution objects of claim 1, wherein the holder comprises:

a stent body having a predetermined shape;

the sponge suction device comprises a support body, a plurality of suction device connecting pieces and a plurality of sponge suction devices, wherein the plurality of suction device connecting pieces are respectively provided with a clamping groove structure matched with the shape of the support body and are sleeved on the support body, each suction device connecting piece can slide along the support body and is fixed at a preset position on the support body through screws, and the plurality of sponge suction devices are respectively fixedly connected with the suction device connecting pieces.

3. The vacuum suction device for logistics objects as set forth in claim 1, further comprising a weighing assembly fixedly installed on top of said support and comprising:

the weighing part is used for measuring the weight of the logistics object adsorbed by the sponge suction tool;

and the limiting part is used for limiting the movement range of the weighing part.

4. The vacuum chuck device for physical distribution objects as claimed in claim 3, wherein said weighing part comprises:

the weighing lower connecting column is fixedly arranged on the bracket;

the weighing sensor is positioned above the weighing lower connecting column, and the lower end of the weighing sensor is connected to the weighing lower connecting column;

and the weighing upper connecting column is positioned above the weighing sensor and is connected with the upper end of the weighing sensor.

5. The vacuum chuck device for physical distribution objects as claimed in claim 4, wherein said stopper portion comprises:

the hollow lower limiting column is fixedly arranged on the bracket, and the upper end of the hollow lower limiting column is provided with a hole;

go up the spacing post, go up the lower extreme of spacing post and extend to in the hole of spacing post upper end under the hollow, and with the cooperation of spacing post formation shaft hole under the hollow, go up the spacing post and have the boss in the bottom, the size of boss is greater than the size of the hole of spacing post upper end under the hollow.

6. The vacuum chuck device for physical distribution objects as claimed in claim 3, wherein the weighing unit comprises a plurality of weighing parts and a plurality of position-limiting parts which are uniformly distributed.

7. The vacuum chuck device for physical distribution objects as claimed in claim 4, wherein said load cell is a tension/compression sensor.

8. The vacuum suction device for objects in logistics according to claim 5, further comprising a driver connector, wherein the lower part of the driver connector is fixedly connected with the weighing upper connecting column and the upper limiting column, and the upper part of the driver connector is fixedly connected with a driver for driving the device.

9. The vacuum suction device for a physical distribution object according to claim 3, further comprising an inertia measuring unit installed on the holder and/or the sponge suction device.

10. The vacuum chuck device for a logistics object of claim 1 further comprising a chuck assembly, said chuck assembly comprising:

the vacuum sucker is communicated with the gas path gas distribution assembly through a gas pipe;

and the sucker mounting rack is used for fixedly mounting the vacuum sucker to the bracket.

11. The vacuum chuck device for a physical distribution object of claim 10, wherein each of the sponge chucks and each of the vacuum chucks has a check valve.

12. The vacuum chuck device for physical distribution object as claimed in claim 10, wherein said gas path gas distribution assembly comprises:

a body having a cavity;

the main air path joint is connected to the negative pressure main air path and communicated with the cavity of the body;

the sponge air path joints are respectively connected to the sponge suckers and are communicated with the cavity of the body;

and the at least one sucker air path joint is respectively connected to the at least one vacuum sucker and is communicated with the cavity of the body.

13. The vacuum chuck device for a physical distribution object according to claim 12, wherein the main air path joint has a rotatable inner bearing, and a connection plane of the main air path joint to the body is sealed by a vacuum O-ring.

14. The vacuum chuck device for physical distribution objects of claim 12, wherein the gas path distribution assembly further comprises a first vacuum gauge for monitoring the gas pressure within the cavity of the body.

15. The vacuum suction device for the logistics object of claim 12, wherein the air path air distribution assembly further comprises a first fixed connector having a first slot-shaped hole and a second slot-shaped hole, the first fixed connector is fixedly mounted to the bracket through the first slot-shaped hole by a screw, and the body of the air path air distribution assembly is fixedly mounted to the first fixed connector through the second slot-shaped hole by a screw.

16. The vacuum suction device for a logistics object of claim 12 further comprising a shunt control valve located on an air path from the air path air distribution assembly to the sponge suction and the vacuum chuck, the shunt control valve comprising:

the second vacuum meter is used for monitoring the air pressure on the air path;

and the vacuum valve is used for controlling the on-off of the gas path.

17. The vacuum suction device for a physical distribution object of claim 1, further comprising a collision detecting assembly, the collision detecting assembly comprising:

the second fixed connecting piece is fixedly connected to a preset position on the bracket through a screw;

the guide post extends along the vertical direction and penetrates through the through hole in the second fixed connecting piece;

the collision block is fixedly connected to the bottom of the guide pillar;

a guide post connecting piece, which is provided with a horizontal part extending horizontally and a vertical part extending downwards from the horizontal part, wherein the horizontal part is fixedly connected with the upper part of the guide post;

the travel switch is provided with a body, a roller and a rotary swing rod, the body is fixedly connected to the second fixed connecting piece, the roller is rotatably connected to the body through the rotary swing rod, and the roller abuts against the guide pillar connecting sheet and is excessively abutted against the vertical part from the horizontal part abutted against the guide pillar connecting sheet along with the rising of the guide pillar connecting sheet.

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