CN221216306U - Full-automatic feed bin - Google Patents

Abstract

The utility model relates to a full-automatic bin which comprises a bin body, a feeding hole and a conveyor belt arranged in the bin body, wherein the bin body is formed by encircling a bin door, a top surface, a bottom surface, a first side surface, a second side surface and a third side surface, the feeding hole is formed in the top surface, the conveyor belt is fixed on the bottom surface, and at least one of the first side surface and the second side surface is provided with a first group of sensing devices and a second group of sensing devices. By utilizing the full-automatic bin designed by the utility model, materials can be uniformly supported on a conveyor belt during discharging, and the accumulation condition of the materials in the bin body and the total amount of the materials can be accurately known by virtue of the first group of sensing devices and the second group of sensing devices; when the material is transferred to the target equipment, the transfer quantity of the material is controlled, and the conveyor belt can convey quantitative material according to the actual working condition. The whole process realizes full automation without complicated manual operation, so that the material transfer is intelligent and convenient.

Description

Full-automatic feed bin

Technical Field

The utility model relates to the technical field of machine manufacturing, in particular to a full-automatic storage bin.

Background

The storage bin is common industrial equipment and is mainly applied to material transfer, transfer and transportation, so that the materials can be timely and accurately sent to target equipment.

In the prior art, baffles are often directly arranged on two sides of a conveyor belt to serve as bins, materials are directly stacked on the conveyor belt during discharging, the conveyor belt is started and stopped by means of experience of workers and naked eyes, but the stacking condition of the materials in the bins is difficult to accurately know, the materials are often stacked at discharging points and are difficult to transfer, and the bins are prone to faults; when the material is transferred to the target equipment, the transfer amount of the material is difficult to control, and the target equipment has the hidden trouble of being damaged.

Accordingly, the prior art has drawbacks and needs to be improved and developed.

Disclosure of utility model

The embodiment of the utility model provides a full-automatic bin, which comprises a bin body, a feeding hole, a conveyor belt arranged in the bin body, a first group of sensing devices and a second group of sensing devices, wherein materials enter the bin body from the feeding hole and are discharged by the conveyor belt, the first group of sensing devices are arranged at intervals along the discharging direction of the materials, the first group of sensing devices are used for detecting the stacking length of the materials, the second group of sensing devices are arranged at intervals along the discharging direction of the materials and are positioned in the vertical direction of the first group of sensing devices, and the second group of sensing devices are used for detecting the maximum stacking height of the materials.

Further, the bin body is formed by enclosing a bin door, a top surface, a bottom surface, a first side surface, a second side surface and a third side surface, the bin door is rotatably connected to the edge of the top surface, the top surface is provided with the feeding port, the bottom surface is provided with the conveyor belt, the first side surface and the second side surface are positioned at two sides of the discharge direction of the conveyor belt, the third side surface is positioned at the starting end of the conveyor belt, at least one of the first side surface and the second side surface is provided with the first group of sensing devices and the second group of sensing devices, and when the first group of sensing devices and the second group of sensing devices are arranged on the first side surface, the second group of sensing devices are arranged at intervals along the length direction of the first side surface and flush with the surface of the conveyor belt for bearing materials, and the first group of sensing devices are arranged at intervals along the length direction of the first side surface and positioned at the top of the first side surface; when the first group of sensing devices and the second group of sensing devices are mounted on the second side face, the second group of sensing devices are arranged at intervals along the length direction of the second side face and flush with the surface of the conveyor belt for receiving materials, and the first group of sensing devices are arranged at intervals along the length direction of the second side face and located at the top of the second side face.

Further, when the first set of sensing devices and the second set of sensing devices are mounted on the first side, the first set of sensing devices comprises at least three first sensors, the first sensors are respectively positioned at two ends and a middle point of the first side, the second set of sensing devices comprises at least three second sensors, and the second sensors are respectively positioned at two ends and a middle point of the first side; when the first group of sensing devices and the second group of sensing devices are mounted on the second side face, the first group of sensing devices at least comprise three first sensors, the first sensors are respectively positioned at two ends and the middle point of the second side face, the second group of sensing devices at least comprise three second sensors, and the second sensors are respectively positioned at two ends and the middle point of the second side face.

Further, the first sensor and the second sensor are photoelectric switches.

Further, the first side and the second side are respectively fixed with a base, the base is provided with a telescopic piece, the fixed end of the telescopic piece is fixed on the base, and the extension end of the telescopic piece is connected with the bin gate.

Further, a feeding chamber is fixed on the top surface, the feeding port is arranged on the top surface of the feeding chamber, a screw rod is arranged in the feeding chamber and used for being matched with the conveyor belt for feeding, a motor is arranged outside the feeding chamber, and a rotating shaft of the screw rod is connected to a rotating shaft of the motor.

Further, the length of the axis of the screw from the most distal end of the screw blade on the screw is equal to the length of the axis of the screw from the top surface.

Further, when the feeding hole is positioned above the starting end of the conveyor belt, the feeding chamber is communicated with the bin body, and the feeding direction of the screw rod is the same as the feeding direction of the conveyor belt.

Further, when the feed inlet is located above the tail end of the conveyor belt, the feed inlet is used for feeding to the feeding chamber, the feeding direction of the screw rod is opposite to that of the conveyor belt, the top surface is provided with the blanking port, the blanking port is located above the starting end of the conveyor belt, and the blanking port is communicated with the feeding chamber and the bin body.

Further, the bottom surface is provided with the fujiu Ma Lun, the fuma wheel comprises a roller and a base, the roller is used for moving the bin body, and the base is used for fixedly supporting the bin body.

The beneficial effects are that:

According to the technical scheme, the utility model provides a full-automatic stock bin:

1. Through setting up first group sensing device and second group sensing device and detect the pile up length and the pile up height of storehouse body material respectively for the pile up of material in the storehouse body presents the visualization, convenient management.

2. Through set up first group sensing device and second group sensing device on first side or second side, first group sensing device can detect the pile up height of piling up the material on the conveyer belt, second group sensing device can detect the pile up length of piling up the material on the conveyer belt, when first group sensing device and second group sensing device detected boring pile up height and pile up length and satisfy the material transfer demand, first group sensing device and second group sensing device can cooperate the conveyer belt to shift the material, and can pass through first group sensing device and second group sensing device to the pile up height of material and pile up the continuous detection of length, thereby the transfer volume of control material has realized automated transportation, intelligence and the convenience of a full-automatic feed bin have been improved.

3. Through the distribution position design to the first sensor among the first group sensing device and the second sensor among the second group sensing device for first sensor can detect the whole pile up the height of material of piling up on the conveyer belt, makes the second sensor can detect the whole pile up length of material of piling up on the conveyer belt, has realized the monitoring that is located the internal material volume of storehouse, has improved the intelligent and the practicality of a full-automatic feed bin.

4. Through designing first sensor and second sensor as photoelectric switch, after the photoelectric switch is sheltered from to the material, photoelectric switch can transmit the signal for the computer, and the computer receives and discerns the signal, handles the signal to control the conveyer belt motion, realized the mechanized operation of conveyer belt, improved the intelligence and the convenience of a full-automatic feed bin.

5. Through being fixed with the base respectively on first side and second side, utilize base installation extensible member, utilize extensible member control door switching, compare and install extensible member material direct impact door and realize the material transfer, after the installation extensible member, the door is difficult to destroyed, can in time reset after the material transfer, has reduced the maintenance cost of a full-automatic feed bin, has improved the practicality of a full-automatic feed bin.

6. Through fixed pay-off room on the top surface, at the indoor hob of installation of pay-off, at the outdoor motor of installation of pay-off, the pivot of motor is connected the rotation axis of hob, and under the drive of motor, helical blade on the hob drives the material and removes, disperses the material, prevents that the material from piling up all the time in same department extrusion destruction feed bin, has improved the security and the practicality of a full-automatic feed bin.

7. Through setting up helical blade's height, prevent helical blade from sheltering from first sensor and second sensor for helical blade's rotation does not influence the operation of first sensor and second sensor, has improved the security and the stability of a full-automatic feed bin.

8. Through the position of design feed inlet, when the feed inlet is located the top of the initiating terminal of conveyer belt, get rid of the top surface, with the pay-off room intercommunication storehouse body, set up the pay-off direction of hob the same with the pay-off direction of conveyer belt, the material can be followed the feed inlet and directly be received by other conveyer belts after falling down, makes things convenient for follow-up transportation, has simplified the process of a full-automatic feed bin, has improved the operating efficiency of a full-automatic feed bin.

9. Through the position of design feed inlet, when the feed inlet setting is in the top that is located the terminal of conveyer belt, the feed inlet is carried the pay-off room with the material, sets up the pay-off direction of hob and the pay-off opposite direction of conveyer belt, when the material that transports needs the homomixer, realizes the homogenization to the material through the hob, because offered the blanking mouth on the top surface, the blanking mouth is located the top of the initiating terminal of conveyer belt moreover, blanking mouth intercommunication pay-off room with the storehouse body, the material after the homogenization is carried on the conveyer belt, again through the transfer of follow-up transport completion material, increased the function of a full-automatic feed bin, improved the practicality and the application scope of a full-automatic feed bin.

10. Through installing fortune Ma Lun on the bottom surface, utilize the gyro wheel removal storehouse body of fortune horse wheel, utilize the base fixed stay storehouse body of fortune horse wheel, the storehouse body can use in different places to adapt to different pay-off environment, improved the application scope and the practicality of a full-automatic feed bin.

By utilizing the full-automatic bin provided by the utility model, materials can be uniformly supported on the conveyor belt during discharging, and the accumulation condition of the materials in the bin body and the total amount of the materials can be accurately known by virtue of the first photoelectric switch and the second photoelectric switch; when the material is transferred to the target equipment, the transfer quantity of the material is controlled, and the conveyor belt can convey quantitative material according to the actual working condition. The whole process realizes full automation without complicated manual operation, so that the material transfer is intelligent and convenient.

It should be understood that all combinations of the foregoing concepts, as well as additional concepts described in more detail below, may be considered a part of the inventive subject matter of the present disclosure as long as such concepts are not mutually inconsistent.

The foregoing and other aspects, embodiments, and features of the present teachings will be more fully understood from the following description, taken together with the accompanying drawings. Other additional aspects of the utility model, such as features and/or advantages of the exemplary embodiments, will be apparent from the description which follows, or may be learned by practice of the embodiments according to the teachings of the utility model.

Drawings

The drawings are not intended to be drawn to scale with respect to true references. In the drawings, each identical or nearly identical component that is illustrated in various figures may be represented by a like numeral. For purposes of clarity, not every component may be labeled in every drawing. Embodiments of various aspects of the utility model will now be described, by way of example, with reference to the accompanying drawings, in which:

fig. 1 is a schematic structural diagram of an embodiment of the present application.

Reference numerals illustrate:

A feeding chamber 1; a feed inlet 101; a conveyor belt 102; a bin gate 103; a telescoping member 104; a first side 105; a second side 106; a first sensor 2; a second sensor 3; a screw rod 4; and a motor 5.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by a person skilled in the art without creative efforts, based on the described embodiments of the present utility model fall within the protection scope of the present utility model. Unless defined otherwise, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs.

The terms "first," "second," and the like in the description and in the claims, are not used for any order, quantity, or importance, but are used for distinguishing between different elements. Also, unless the context clearly indicates otherwise, singular forms "a," "an," or "the" and similar terms do not denote a limitation of quantity, but rather denote the presence of at least one.

The terms "comprises," "comprising," or the like are intended to cover a feature, integer, step, operation, element, and/or component recited as being present in the element or article that "comprises" or "comprising" does not exclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof. "up", "down", "left", "right" and the like are used only to indicate a relative positional relationship, and when the absolute position of the object to be described is changed, the relative positional relationship may be changed accordingly.

In the prior art, baffles are often directly arranged on two sides of a conveyor belt to serve as bins, materials are directly stacked on the conveyor belt during discharging, the conveyor belt is started and stopped by means of experience of workers and naked eyes, but the stacking condition of the materials in the bins is difficult to accurately know, the materials are often stacked at discharging points and are difficult to transfer, and the bins are prone to faults; when the material is transferred to the target equipment, the transfer amount of the material is difficult to control, and the target equipment has the hidden trouble of being damaged.

In view of this, the present utility model contemplates a fully automatic bin comprising a bin body, a feed inlet 101, and a conveyor belt 102 disposed inside the bin body, wherein a material enters the bin body from the feed inlet 101 and is discharged by the conveyor belt 102, characterized by further comprising a first set of sensor devices disposed at intervals along a discharge direction of the material, for detecting a stacking length of the material, and a second set of sensor devices disposed at intervals along the discharge direction of the material and disposed in a vertical direction of the first set of sensor devices, for detecting a maximum stacking height of the material.

Through setting up first group sensing device and second group sensing device and detecting the pile up length and the pile up height of storehouse body material respectively for the pile up of material in the storehouse body can be detected by first group sensing device and second group sensing device, presents the visualization, convenient management.

The bin body is formed by enclosing a bin door 103, a top surface, a bottom surface, a first side surface 105, a second side surface 106 and a third side surface, wherein the bin door 103 can be rotatably connected with the edge of the top surface, the top surface is provided with a feeding hole 101, the bottom surface is provided with a conveyor belt 102, the first side surface 105 and the second side surface 106 are positioned at two sides of the discharge direction of the conveyor belt 102, the third side surface is positioned at the starting end of the conveyor belt 102,

At least one of the first side 105 and the second side 106 is provided with a first group of sensing devices and a second group of sensing devices, when the first group of sensing devices and the second group of sensing devices are arranged on the first side 105, the second group of sensing devices are arranged at intervals along the length direction of the first side 105 and are flush with the surface of the conveyor belt 102 for receiving materials, and the first group of sensing devices are arranged at intervals along the length direction of the first side 105 and are positioned at the top of the first side 105; when the first and second sets of sensing devices are mounted on the second side 106, the second set of sensing devices are disposed at intervals along the length direction of the second side 106 and flush with the surface of the conveyor belt 102 on which the material is received, and the first set of sensing devices are disposed at intervals along the length direction of the second side 106 and located at the top of the second side 106.

Referring to fig. 1, the material undergoes the following operations when it needs to be transferred: when the feeding port 101 is positioned above the starting end of the conveyor belt 102, materials are fed into the bin body through the feeding port 101, at this time, the materials are piled up on the conveyor belt 102 at the position right opposite to the feeding port 101, when the second sensor 3 positioned at the starting end of the conveyor belt 102 detects the materials, the motor 5 is started manually or the first sensor 2 positioned at the starting end of the conveyor belt 102 transmits signals to the computer to identify processing and control the motor 5 to start, the screw rod 4 is driven to operate, the screw rod 4 rotates to drive the screw blade of the screw rod 4 to rotate, the screw blade drives the materials to move, the materials are piled up in the bin under the rotation of the screw rod 4, and when the materials are detected to reach the maximum piling length by the first sensor 2 positioned near the tail end of the conveyor belt 102, the motor 5 stops the screw rod 4 to operate in a manual or signal to the computer to identify processing and control the motor 5 to start, and the bin is completed. After the target equipment for transferring the materials is set, the telescopic rod pushes the materials or transmits signals to a computer through the first sensor 2 positioned at the tail end of the conveyor belt 102 to identify the mode of processing and controlling the telescopic rod to stretch, the bin door 103 is opened, the conveyor belt 102 operates, and the materials are driven to be transferred into the target equipment.

For example, when 1/5 of the materials in the bin need to be transferred, if the first side 105 and the second side 106 are provided with the first set of sensing devices and the second set of sensing devices, the first side 105 and the second side 106 may be divided into five equal divisions, and the first sensor 2 and the second sensor 3 are additionally arranged on the equal division line, at this time, 6 first sensors 2 and 6 second sensors 3 are all arranged, 6 first sensors 2 are arranged on two ends and equal division lines of the first side 105 and the second side 106, and 6 second sensors 3 are arranged on two ends and equal division lines of the first side 105 and the second side 106. The conveyor belt 102 is opened to bring the material into the destination device, and when the first sensor 2 near the start end of the conveyor belt 102 does not detect the material and the first sensor 2 located on the fifth line closest to the start end of the conveyor belt 102 does not detect the material, and the second sensor 3 located at the start end of the conveyor belt 102 does not detect the material and the second sensor 3 located on the fifth line closest to the start end of the conveyor belt 102 does not detect the material, the conveyor belt 102 stops running, and the conveyor belt 102 successfully transfers 1/5 of the material in the bin to the destination device.

When the first group of sensing devices and the second group of sensing devices are installed on the first side face 105, the first group of sensing devices at least comprise three first sensors 2, the first sensors 2 are respectively positioned at two ends and the middle point of the first side face 105, the second group of sensing devices at least comprise three second sensors 3, and the second sensors 3 are respectively positioned at two ends and the middle point of the first side face 105; when the first set of sensing devices and the second set of sensing devices are mounted on the second side 106, the first set of sensing devices at least comprises three first sensors 2, the first sensors 2 are respectively located at two ends and a middle point of the second side 106, the second set of sensing devices at least comprises three second sensors 3, and the second sensors 3 are respectively located at two ends and a middle point of the second side 106.

By providing the first side 105 or the second side 106 with a first set of sensor means and a second set of sensor means, the first set of sensor means and the second set of sensor means are parallel to each other, the second set of sensor means being located in the vertical direction of the first set of sensor means. The first group of sensing devices can detect the stacking height of materials stacked on the conveyor belt 102, the second group of sensing devices can detect the stacking length of materials stacked on the conveyor belt 102, when the stacking height and the stacking length of the materials detected by the first group of sensing devices and the second group of sensing devices meet the material transfer requirement, the first group of sensing devices and the second group of sensing devices can cooperate with the conveyor belt 102 to transfer the materials, and the stacking height and the stacking length of the materials can be continuously detected through the first group of sensing devices and the second group of sensing devices, so that the transfer quantity of the materials is controlled, automatic transportation is realized, and the intelligence and convenience of a full-automatic storage bin are improved.

Through the distribution position design to the first sensor 2 among the first group sensing device and the second sensor 3 among the second group sensing device for the first sensor 2 can detect the whole pile height of piling up the material on the conveyer belt 102, makes the second sensor 3 can detect the whole pile length of piling up the material on the conveyer belt 102, has realized the monitoring that is located the internal material volume of storehouse, has improved the intelligent and the practicality of a full-automatic feed bin.

The first sensor 2 and the second sensor 3 are photoelectric switches.

Through designing first sensor 2 and second sensor 3 as photoelectric switch, after the photoelectric switch is sheltered from to the material, photoelectric switch can transmit the signal for the computer, and the computer receives and discerns the signal, handles the signal to control conveyer belt 102 motion, realized the mechanized operation of conveyer belt 102, improved the intelligent and the convenience of a full-automatic feed bin.

One end of the top surface, which is close to the conveyor belt, is rotatably connected with a bin gate 103, and the height of the bin gate 103 is equal to the height of the top surface from the bottom surface.

Referring to fig. 1, there is a possibility that the material is extruded from the bin body after being gradually piled up in the bin body, compared with the case that the bin gate 103 is not provided, so that the bin gate 103 needs to be designed to reduce the waste of the material. Through setting up rotatable door 103 on the limit that is located the top surface and is relative the third side, door 103 can restrict the material that is located the conveyer belt 102 end in the storehouse is internal, prevents that the material is unrestrained, extravagant, has improved the practicality of a full-automatic feed bin.

The first side 105 and the second side 106 are respectively fixed with a base, the base is provided with a telescopic piece 104, the fixed end of the telescopic piece 104 is fixed on the base, and the extension end of the telescopic piece 104 is connected with the bin gate 103.

The width of the bin gate 103 is greater than the distance between the first side 105 and the second side 106, and after the bases are respectively fixed on the first side 105 and the second side 106, the bases are convenient for installing the telescopic members 104, and the telescopic ends of the telescopic members 104 are provided with installing positions. Utilize extensible member 104 control door 103 switching, compare and not install extensible member 104 material and directly strike door 103 and realize the material and shift, install extensible member 104 after, door 103 is difficult to be destroyed, can in time reset after the material shifts, has reduced the maintenance cost of a full-automatic feed bin, has improved the practicality of a full-automatic feed bin.

A feeding chamber 1 is fixed on the top surface, a feeding port 101 is arranged on the top surface of the feeding chamber 1, a screw rod 4 is arranged in the feeding chamber 1, the screw rod 4 is used for feeding by matching with a conveyor belt 102, a motor 5 is arranged outside the feeding chamber 1, and a rotating shaft of the screw rod 4 is connected with a rotating shaft of the motor 5.

Through fixed pay-off room 1 on the top surface, install hob 4 in pay-off room 1, install motor 5 outside pay-off room 1, connect the pivot of motor 5 with the rotation axis of hob 4, under motor 5's drive, helical blade on hob 4 drives the material and removes, disperses the material, prevents that the material from piling up all the time in same department extrusion destruction feed bin, has improved the security and the practicality of a full-automatic feed bin.

The length of the axis of the screw 4 from the most distal end of the screw blade on the screw 4 is equal to the length of the axis of the screw 4 from the top surface.

Through setting up helical blade's height, prevent helical blade from sheltering from first sensor 2 and second sensor 3 for helical blade's rotation does not influence the operation of first sensor 2 and second sensor 3, has improved the security and the stability of a full-automatic feed bin.

When the feeding port 101 is positioned above the starting end of the conveyor belt 102, the feeding chamber 1 is communicated with the bin body, and the feeding direction of the screw rod 4 is the same as the feeding direction of the conveyor belt 102.

Through the position of design feed inlet 101, when feed inlet 101 is located the top of the starting end of conveyer belt 102, get rid of the top surface, with the feeding chamber 1 intercommunication storehouse body, set up the pay-off direction of hob 4 to be the same with the pay-off direction of conveyer belt 102, the material can be followed the feed inlet 101 and fallen the direct conveyer belt 102 receipt of respectively of back, makes things convenient for follow-up transportation, has simplified the process of a full-automatic feed bin, has improved the operating efficiency of a full-automatic feed bin.

When the feed inlet 101 is located above the tail end of the conveyor belt 102, the feed inlet 101 is used for feeding to the feeding chamber 1, the feeding direction of the screw rod 4 is opposite to that of the conveyor belt 102, the top surface is provided with a blanking opening, the blanking opening is located above the starting end of the conveyor belt 102, and the blanking opening is communicated with the feeding chamber 1 and the bin body.

Through the position of design feed inlet 101, when feed inlet 101 setting is in the top that is located the end of conveyer belt 102, feed inlet 101 is with the material delivery to pay-off room 1, set up the pay-off direction of hob 4 and the pay-off opposite direction of conveyer belt 102, when the material that transports needs evenly to mix, realize homogenizing to the material through hob 4, because offered the blanking mouth on the top surface, the blanking mouth is located the top of the starting end of conveyer belt 102 moreover, blanking mouth intercommunication pay-off room 1 and the storehouse body, the material after the homogenization is sent to on the conveyer belt 102, transfer through follow-up transport completion material has increased the function of a full-automatic feed bin, practicality and application scope of a full-automatic feed bin have been improved.

And the bottom surface is provided with a blessing Ma Lun, the blessing horse wheel comprises a roller and a base, the roller is used for moving the bin body, and the base is used for fixedly supporting the bin body.

Fu Ma Lun is a multifunctional castor which integrates movement and fixation. The fuma wheel also comprises a roller, and the roller of the fuma wheel is grounded by rotating the roller of the Gao Fuma wheel, so that the base of the fuma wheel is emptied and the bin can be transferred; the roller wheel of the fuma wheel is emptied by reversely rotating the roller wheel of the Gao Fuma wheel, the base of the fuma wheel is grounded, and the bin body can be fixed. Through installing fortune Ma Lun on the bottom surface, utilize the gyro wheel removal storehouse body of fortune horse wheel, utilize the base fixed stay storehouse body of fortune horse wheel, the storehouse body can use in different places to adapt to different pay-off environment, improved the application scope and the practicality of a full-automatic feed bin.

In summary, according to the full-automatic bin provided by the utility model, materials can be uniformly received on the conveyor belt 102 during discharging, and the accumulation condition of the materials in the bin body and the total amount of the materials can be accurately known by virtue of the first photoelectric switch and the second photoelectric switch; when the material is transferred to the destination device, the transfer amount of the material is controlled, and the conveyor belt 102 can convey a fixed amount of the material according to the actual condition. The whole process realizes full automation without complicated manual operation, so that the material transfer is intelligent and convenient.

While the utility model has been described with reference to preferred embodiments, it is not intended to be limiting. Those skilled in the art will appreciate that various modifications and adaptations can be made without departing from the spirit and scope of the present utility model. Accordingly, the scope of the utility model is defined by the appended claims.

Claims (10)

1. The utility model provides a full-automatic feed bin, includes the storehouse body, feed inlet and sets up the internal conveyer belt in storehouse, the material is followed the feed inlet gets into the internal portion in storehouse and by the conveyer belt carries out the ejection of compact, its characterized in that still includes first group sensing device and second group sensing device, first group sensing device sets up along the ejection of compact direction interval of material, first group sensing device is used for detecting the pile up length of material, second group sensing device sets up and is located along the ejection of compact direction interval of material on the vertical direction of first group sensing device, second group sensing device is used for detecting the biggest pile up height of material.

2. The full-automatic bunker according to claim 1, wherein the bunker body is formed by enclosing a bunker door, a top surface, a bottom surface, a first side surface, a second side surface and a third side surface, the bunker door is rotatably connected to the edge of the top surface, the top surface is provided with the feeding port, the bottom surface is provided with the conveyor belt, the first side surface and the second side surface are positioned at two sides of the discharging direction of the conveyor belt, the third side surface is positioned at the starting end of the conveyor belt,

At least one of the first side surface and the second side surface is provided with the first group of sensing devices and the second group of sensing devices, when the first group of sensing devices and the second group of sensing devices are arranged on the first side surface, the second group of sensing devices are arranged at intervals along the length direction of the first side surface and are flush with the surface of the conveyor belt for receiving materials, and the first group of sensing devices are arranged at intervals along the length direction of the first side surface and are positioned at the top of the first side surface; when the first group of sensing devices and the second group of sensing devices are mounted on the second side face, the second group of sensing devices are arranged at intervals along the length direction of the second side face and flush with the surface of the conveyor belt for receiving materials, and the first group of sensing devices are arranged at intervals along the length direction of the second side face and located at the top of the second side face.

3. The fully automatic bin of claim 2, wherein when the first and second sets of sensing devices are mounted on the first side, the first set of sensing devices includes at least three first sensors at each of the two ends and the midpoint of the first side, and the second set of sensing devices includes at least three second sensors at each of the two ends and the midpoint of the first side; when the first group of sensing devices and the second group of sensing devices are mounted on the second side face, the first group of sensing devices at least comprise three first sensors, the first sensors are respectively positioned at two ends and the middle point of the second side face, the second group of sensing devices at least comprise three second sensors, and the second sensors are respectively positioned at two ends and the middle point of the second side face.

4. A fully automatic bunker according to claim 3, wherein the first sensor and the second sensor are photoelectric switches.

5. The fully automatic storage bin according to claim 2, wherein bases are respectively fixed on the first side face and the second side face, telescopic members are mounted on the bases, fixed ends of the telescopic members are fixed on the bases, and extension ends of the telescopic members are connected to the bin gate.

6. The full-automatic feed bin according to claim 2, wherein a feeding chamber is fixed on the top surface, the feeding port is formed in the top surface of the feeding chamber, a screw rod is installed in the feeding chamber and used for feeding in cooperation with the conveyor belt, a motor is installed outside the feeding chamber, and a rotating shaft of the screw rod is connected to a rotating shaft of the motor.

7. The fully automatic storage bin of claim 6 wherein the length of the axis of the screw from the distal most end of the screw blade on the screw is equal to the length of the axis of the screw from the top surface.

8. The fully automatic storage bin according to claim 6, wherein when the feeding hole is located above the starting end of the conveyor belt, the feeding chamber is communicated with the bin body, and the feeding direction of the screw rod is the same as the feeding direction of the conveyor belt.

9. The fully automatic storage bin according to claim 6, wherein when the feeding hole is located above the tail end of the conveyor belt, the feeding hole is used for feeding to the feeding chamber, the feeding direction of the screw rod is opposite to that of the conveyor belt, the top surface is provided with a blanking hole, the blanking hole is located above the starting end of the conveyor belt, and the blanking hole is communicated with the feeding chamber and the bin body.

10. The fully automatic bin of claim 2 wherein said bottom surface has a frame Ma Lun mounted thereon, said frame wheel including rollers for moving said bin body and a base for fixedly supporting said bin body.