CN213386612U - Material loading temporary storage device - Google Patents

Abstract

The utility model discloses a feeding temporary storage device, which comprises a frame, a vibration disc, a material guiding and blocking mechanism, a temporary storage mechanism and a detection mechanism, wherein the vibration disc, the material guiding and blocking mechanism, the temporary storage mechanism and the detection mechanism are arranged on the frame; the material guiding and blocking mechanism comprises a material guiding and blocking seat and a first driving piece capable of driving the material guiding and blocking seat to reciprocate in a first direction, a material guiding groove and a first material blocking piece are arranged on the material guiding and blocking seat, and the material guiding groove and the first material blocking piece are sequentially arranged along the first direction; the temporary storage mechanism is provided with an arc temporary storage groove for temporarily storing materials, and the arc temporary storage groove is provided with a feed inlet and a discharge outlet provided with a second material retaining piece; the detection mechanism can detect whether the arc temporary storage groove is filled with materials or not, and is in communication connection with the first driving piece; the material guide and material stop seat is provided with a material guide position and a material stop position in the first direction, and when the material guide and material stop seat is positioned at the material guide position, the material guide groove is communicated with a material inlet of the arc temporary storage groove and a material outlet of the vibration disc; when the material guiding and blocking seat is located at the material blocking position, the first material blocking part blocks the discharge hole of the vibrating disc.

Description

Material loading temporary storage device

Technical Field

The utility model relates to a production facility technical field especially relates to a material loading temporary storage device.

Background

The existing feeding device adopts the action mode of single feeding and material taking of the vibration disc, the action flow is complicated, the problem that materials and materials need to be taken and placed for many times in the production process is caused, and the production efficiency is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a material loading temporary storage device, this material loading temporary storage device have stronger stability and reliability.

To achieve the purpose, the utility model adopts the following technical proposal:

a loading temporary storage device comprises a rack, a vibrating disc, a material guiding and blocking mechanism, a temporary storage mechanism and a detection mechanism, wherein the detection mechanism, the temporary storage mechanism, the material guiding and blocking mechanism and the vibrating disc are all arranged on the rack;

the material guiding and blocking mechanism comprises a material guiding and blocking seat and a first driving piece capable of driving the material guiding and blocking seat to reciprocate in a first direction, a material guiding groove and a first material blocking piece are arranged on the material guiding and blocking seat, and the material guiding groove and the first material blocking piece are sequentially arranged along the first direction; the temporary storage mechanism is provided with an arc temporary storage groove for temporarily storing materials, and the arc temporary storage groove is provided with a feed inlet and a discharge outlet provided with a second material retaining piece; the detection mechanism can detect whether the arc temporary storage groove is filled with the materials or not, and is in communication connection with the first driving piece;

the material guiding and blocking seat is provided with a material guiding position and a material blocking position in the first direction, and when the material guiding and blocking seat is located at the material guiding position, the material guiding groove conducts a material inlet of the arc-shaped temporary storage groove and a material outlet of the vibrating disc; when the material guide and the material blocking seat are located at the material blocking position, the first material blocking part blocks the discharge hole of the vibrating disc.

In some embodiments, the temporary storage mechanism comprises a storage tray and two opposite pushing assemblies, the storage tray is provided with a first arc-shaped side surface, and the first arc-shaped side surface is connected with a temporary storage supporting plate;

each pushing assembly comprises a pushing piece with a second arc-shaped side surface and a second driving piece capable of driving the pushing piece to do linear reciprocating motion, and each pushing piece is sequentially provided with a material taking position, a limiting position and a pushing position in the direction of the linear reciprocating motion;

when the pushing pieces are located at the limiting positions, the first arc-shaped side surfaces, the temporary storage supporting plate and the second arc-shaped side surfaces of the two pushing pieces form the arc-shaped temporary storage groove in an enclosing mode; when the pushing piece is located at the pushing position, the pushing piece can push the materials in the arc temporary storage groove tightly; when the pushing piece is located at the material taking position, a material taking gap exists between the pushing piece and the temporary storage supporting plate.

In some embodiments, the second driving member is an electric cylinder, an air cylinder, a hydraulic cylinder or an electric push rod, and each push member is connected to the output shaft of the corresponding second driving member; and a compression spring is sleeved on the output shaft of each second driving piece.

In some embodiments, the pushing assembly further includes a second guide assembly guiding the linear reciprocating motion of the pushing member, the second guide assembly includes a slider and a guide rail, the guide rail extends along the linear reciprocating motion direction of the pushing member, the slider is slidably connected with the guide rail, and the pushing member is connected to the slider.

In some embodiments, the temporary storage mechanism further includes a third driving element, and the third driving element can drive the second blocking member to reciprocate along the second direction, so that the second blocking member is close to the discharge hole of the arc-shaped temporary storage groove and blocks the discharge hole of the arc-shaped temporary storage groove or the second blocking member leaves the discharge hole of the arc-shaped temporary storage groove.

In some embodiments, the third drive is an air cylinder, a hydraulic cylinder, or an electric push rod.

In some embodiments, the detection mechanism includes a plurality of optical fiber sensors, the optical fiber sensors are evenly spaced along the circumferential direction of the arc-shaped temporary storage groove, and a gap between two adjacent optical fiber sensors is smaller than the minimum length of the material.

In some embodiments, the material guiding and blocking mechanism further includes a material guiding limiting plate, and the material guiding limiting plate is covered on the top of the material guiding chute.

In some embodiments, the material guiding and stopping mechanism further comprises a first guide assembly, the first guide assembly comprises a movable block and a guide rod, and the guide rod extends along the first direction; the movable block is sleeved on the guide rod and connected with the material guide and the material blocking seat, and the first driving piece can drive the movable block to drive the material guide and the material blocking seat to move back and forth along the guide rod.

In some embodiments, the first drive member is a pneumatic cylinder, a hydraulic cylinder, or an electric push rod.

The utility model discloses following beneficial effect has at least:

the utility model discloses material loading temporary storage device's guide and fender material seat are equipped with guide position and keep off the material position in the first direction, and when guide and fender material seat were located the guide position, the baffle box switched on the pan feeding mouth of arc temporary storage groove and the discharge gate of vibration dish, and the material in the vibration dish gets into arc temporary storage groove and keeps in; when detection mechanism detected that the arc groove of keeping in was full of the material, first driving piece drive guide and fender material seat moved to keeping off the material position, made first fender material piece block the discharge gate of vibration dish, the material of vibration dish stops to get into the arc groove of keeping in. The utility model discloses material loading temporary storage device has realized keeping in steadily and high-efficiently material loading, has retrencied and has got material action flow, and the significantly reduced is got and is put the material time, effectively improves production efficiency.

Drawings

Fig. 1 is a schematic structural view of a feeding temporary storage device according to an embodiment of the present invention;

FIG. 2 is an enlarged view of a portion A of the temporary loading unit shown in FIG. 1;

fig. 3 is a schematic structural view of a material guiding and blocking mechanism in the material loading temporary storage device shown in fig. 1;

fig. 4 is a schematic structural diagram of a temporary storage mechanism and a detection mechanism in the feeding temporary storage device shown in fig. 1.

The reference numbers illustrate:

10. a frame; 20. a vibrating pan; 30. a material guiding and blocking mechanism; 31. a material guiding and blocking seat; 32. a first driving member; 33. a first material blocking part; 34. a material guide limit plate; 35. a movable block; 36. a guide bar; 40. a temporary storage mechanism; 41. storing a material tray; 42. a second material blocking part; 43. pushing the material piece; 44. a second driving member; 45. a guide rail; 46. a third driving member; 51. an optical fiber sensor.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

This embodiment provides a material loading temporary storage device, and this material loading temporary storage device can be applied to the material loading of material in the production process and keep in.

As shown in fig. 1 to 4, the feeding temporary storage device includes a frame 10, a vibrating tray 20, a material guiding and blocking mechanism 30, a temporary storage mechanism 40 and a detection mechanism, wherein the detection mechanism, the temporary storage mechanism 40, the material guiding and blocking mechanism 30 and the vibrating tray 20 are all disposed on the frame 10; the material guiding and blocking mechanism 30 comprises a material guiding and blocking seat 31 and a first driving piece 32 capable of driving the material guiding and blocking seat 31 to reciprocate in a first direction, a material guiding groove and a first material blocking piece 33 are arranged on the material guiding and blocking seat 31, and the material guiding groove and the first material blocking piece 33 are sequentially arranged along the first direction; the temporary storage mechanism 40 is provided with an arc temporary storage groove for temporarily storing materials, and the arc temporary storage groove is provided with a feed inlet and a discharge outlet provided with a second material blocking piece 42; the detection mechanism can detect whether the arc temporary storage groove is full of materials or not, and is in communication connection with the first driving piece 32; the material guiding and blocking seat 31 is provided with a material guiding position and a material blocking position in the first direction, and when the material guiding and blocking seat 31 is located at the material guiding position, the material guiding groove conducts the material inlet of the arc-shaped temporary storage groove and the material outlet of the vibrating disc 20; when the material guiding and blocking seat 31 is located at the material blocking position, the first material blocking member 33 blocks the discharge hole of the vibrating plate 20.

In the feeding temporary storage device, the material guiding and blocking seat 31 is provided with a material guiding position and a material blocking position in the first direction, when the material guiding and blocking seat 31 is located at the material guiding position, the material guiding groove conducts the material inlet of the arc temporary storage groove and the material outlet of the vibration disc 20, and the material in the vibration disc 20 enters the arc temporary storage groove for temporary storage; when the detection mechanism detects that the arc-shaped temporary storage groove is filled with materials, the first driving piece 32 drives the material guide and the material blocking seat 31 to move to the material blocking position, so that the first material blocking piece 33 blocks the discharge hole of the vibration disc 20, and the materials of the vibration disc 20 stop entering the arc-shaped temporary storage groove. The utility model discloses material loading temporary storage device has realized keeping in steadily and high-efficiently material loading, has retrencied and has got material action flow, and the significantly reduced is got and is put the material time, effectively improves production efficiency.

Alternatively, the first driving member 32 may be an air cylinder, a hydraulic cylinder or an electric push rod, as long as it can drive the material guiding and blocking seat 31 to reciprocate in the first direction.

In some embodiments, the guiding and stopping mechanism 30 further includes a guiding position limiting plate 34, and the guiding position limiting plate 34 covers the top of the guiding chute to prevent the material from tilting when the guiding chute is pushed to move forward.

Further, in order to improve the stability of the material guiding and blocking mechanism 31 during the reciprocating movement in the first direction, the material guiding and blocking mechanism 30 further includes a first guiding assembly, as shown in fig. 3, the first guiding assembly includes a movable block 35 and a guiding rod 36, and the guiding rod 36 extends along the first direction; the movable block 35 is sleeved on the guide rod 36 and connected with the material guiding and blocking seat 31; the first driving member 32 can drive the movable block 35 to drive the material guiding and blocking seat 31 to reciprocate along the guide rod 36.

As shown in fig. 4, in some embodiments, the temporary storage mechanism 40 includes a material storage tray 41 and two material pushing assemblies oppositely arranged, the material storage tray 41 has a first arc-shaped side surface, and a temporary storage supporting plate is connected to the first arc-shaped side surface; each pushing assembly comprises a pushing piece 43 with a second arc-shaped side surface and a second driving piece 44 capable of driving the pushing piece 43 to do linear reciprocating motion, and each pushing piece 43 is sequentially provided with a material taking position, a limiting position and a pushing position in the direction of the linear reciprocating motion; when the pushing members 43 are located at the limiting positions, the first arc-shaped side surfaces, the temporary storage supporting plate and the second arc-shaped side surfaces of the two pushing members 43 form an arc-shaped temporary storage groove in an enclosing mode; when the pushing member 43 is located at the pushing position, the pushing member 43 can push the materials in the arc temporary storage groove tightly; when the pushing member 43 is located at the material taking position, a material taking gap exists between the pushing member 43 and the temporary storage supporting plate.

Alternatively, the second drive 44 may be an electric cylinder, an air cylinder, a hydraulic cylinder or an electric push rod, preferably an electric cylinder, the positioning of which is more precise; each pushing member 43 is connected to the output shaft of the corresponding second driving member 44, and the output shaft of each second driving member 44 is sleeved with a compression spring. The elasticity of compression spring has the effect that will push away material piece 43 toward keeping away from second driving piece 44 and push away when material piece 43 is located and pushes away tight position, and compression spring's elasticity enables to push away material piece 43 and floats and push away the material in the arc groove of keeping in, avoids damaging the surface of material.

Further, in order to improve the stability of the pushing member 43 during the linear reciprocating motion, the pushing assembly further comprises a second guiding assembly for guiding the pushing member 43 during the linear reciprocating motion, the second guiding assembly comprises a sliding block and a guide rail 45, the guide rail 45 extends along the linear reciprocating motion direction of the pushing member 43, the sliding block is connected with the guide rail 45 in a sliding manner, and the pushing member 43 is connected to the sliding block.

In some embodiments, the buffer mechanism 40 further includes a third driving member 46, and the third driving member 46 can drive the second blocking member 42 to reciprocate along the second direction, so that the second blocking member 42 is close to the discharge opening of the arc-shaped buffer slot and blocks the discharge opening of the arc-shaped buffer slot or the second blocking member 42 is away from the discharge opening of the arc-shaped buffer slot. Alternatively, the third drive member 46 may be an air cylinder, a hydraulic cylinder, or an electric push rod.

In some embodiments, the detection mechanism includes a plurality of optical fiber sensors 51 (as shown in fig. 4), the optical fiber sensors 51 are uniformly spaced along the circumferential direction of the arc-shaped temporary storage slot, and the gap between two adjacent optical fiber sensors 51 is smaller than the minimum length of the material. Specifically, a plurality of optical fiber sensors 51 are uniformly distributed below the arc-shaped temporary storage tank, and each optical fiber sensor 51 is used for sensing that no magnet exists at a corresponding position of the arc-shaped temporary storage tank.

Taking materials as an example, the working principle of the feeding temporary storage device shown in fig. 1 to 4 is as follows:

(1) the second driving piece 44 drives the pushing pieces 43 to move to a limiting position, an arc temporary storage groove is defined by the first arc-shaped side surface of the material storage disc 41, the temporary storage supporting plate and the second arc-shaped side surfaces of the two pushing pieces 43, and a gap between the second arc-shaped side surface of the pushing piece 43 and the first arc-shaped side surface of the material storage disc 41 meets the requirement that a magnet smoothly passes through;

(2) the third driving piece 46 drives the second blocking piece 42 to move along the second direction to block the discharge hole of the arc-shaped temporary storage groove so as to limit the magnet in the arc-shaped temporary storage groove;

(3) the first driving piece 32 drives the material guide and the material blocking seat 31 to move to a material guide position along a first direction, the material guide groove is flush with the discharge hole of the vibration disc 20 and the material inlet of the arc temporary storage groove, and at the moment, the material guide groove is communicated with the vibration disc 20 and the arc temporary storage groove;

(4) the vibration disc 20 supplies materials to provide a power source for the magnets to push forwards, the magnets sequentially enter the arc-shaped temporary storage groove under the driving of the vibration disc 20, and the optical fiber sensors 51 are uniformly distributed below the arc-shaped temporary storage groove at intervals along the circumferential direction of the arc-shaped temporary storage groove to sense whether the arc-shaped temporary storage groove is filled with the magnets or not;

(5) when the arc temporary storage groove is filled with magnets, that is, each optical fiber sensor 51 outputs a material signal, the first driving member 32 drives the material guiding and blocking seat 31 to move to the material blocking position along the first direction, so that the first material blocking member 33 blocks the discharge hole of the vibration disc 20, and the feeding is cut off; the second driving piece 44 drives the pushing piece 43 to move to the pushing position, and at this time, the pushing piece 43 pushes the magnet in the arc temporary storage groove; the third driving member 46 drives the second blocking member 42 to move along the second direction, so that the second blocking member 42 leaves the discharge hole of the arc-shaped temporary storage groove;

(6) when the material is taken, the second driving member 44 is driven to the material taking position, and at this time, a material taking gap exists between the material pushing member 43 and the temporary storage supporting plate, so that the material is conveniently taken.

In summary, the feeding temporary storage device provided by the embodiment solves the problem of multiple material taking and placing caused by single material feeding of the vibrating disc 20, simplifies the material taking action process, greatly reduces the material taking and placing time, and effectively improves the production efficiency and the assembly precision; and the feeding temporary storage device has stable and reliable performance, exquisite and compact structure, reasonable layout and convenient installation, debugging and maintenance.

It should be noted that when one portion is referred to as being "secured to" another portion, it may be directly on the other portion or there may be an intervening portion. When a portion is said to be "connected" to another portion, it may be directly connected to the other portion or intervening portions may be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A material loading temporary storage device is characterized by comprising a rack (10), a vibrating disc (20), a material guiding and blocking mechanism (30), a temporary storage mechanism (40) and a detection mechanism, wherein the detection mechanism, the temporary storage mechanism (40), the material guiding and blocking mechanism (30) and the vibrating disc (20) are all arranged on the rack (10);

the material guiding and blocking mechanism (30) comprises a material guiding and blocking seat (31) and a first driving piece (32) capable of driving the material guiding and blocking seat (31) to reciprocate in a first direction, a material guiding groove and a first material blocking piece (33) are arranged on the material guiding and blocking seat (31), and the material guiding groove and the first material blocking piece (33) are sequentially arranged along the first direction; the temporary storage mechanism (40) is provided with an arc temporary storage groove for temporarily storing materials, and the arc temporary storage groove is provided with a feed inlet and a discharge outlet provided with a second material retaining piece (42); the detection mechanism can detect whether the arc temporary storage groove is filled with the materials or not, and is in communication connection with the first driving piece (32);

the material guiding and blocking seat (31) is provided with a material guiding position and a material blocking position in the first direction, and when the material guiding and blocking seat (31) is located at the material guiding position, the material guiding groove conducts a material inlet of the arc-shaped temporary storage groove and a material outlet of the vibration disc (20); when the material guide and material blocking seat (31) is located at the material blocking position, the first material blocking part (33) blocks the material outlet of the vibrating disc (20).

2. A temporary loading storage device according to claim 1, wherein the storage mechanism (40) comprises a storage tray (41) and two pushing assemblies oppositely arranged, the storage tray (41) has a first arc-shaped side surface, and the first arc-shaped side surface is connected with a temporary storage supporting plate;

each pushing assembly comprises a pushing piece (43) with a second arc-shaped side surface and a second driving piece (44) capable of driving the pushing piece (43) to do linear reciprocating motion, and each pushing piece (43) is sequentially provided with a material taking position, a limiting position and a pushing position in the linear reciprocating motion direction;

when the pushing parts (43) are located at the limiting positions, the first arc-shaped side surfaces, the temporary storage supporting plate and the second arc-shaped side surfaces of the two pushing parts (43) form the arc-shaped temporary storage groove in an enclosing manner; when the pushing piece (43) is located at the pushing position, the pushing piece (43) can push the materials in the arc temporary storage groove tightly; when the pushing piece (43) is located at the material taking position, a material taking gap exists between the pushing piece (43) and the temporary storage supporting plate.

3. A charge buffer according to claim 2, wherein the second drive member (44) is an electric cylinder, an air cylinder, a hydraulic cylinder or an electric push rod, and each push member (43) is connected to an output shaft of the corresponding second drive member (44); and a compression spring is sleeved on the output shaft of each second driving piece (44).

4. A loading buffer as in claim 2, wherein the pushing assembly further comprises a second guiding assembly for guiding the linear reciprocating motion of the pushing member (43), the second guiding assembly comprises a sliding block and a guiding rail (45), the guiding rail (45) extends along the linear reciprocating motion direction of the pushing member (43), the sliding block is slidably connected with the guiding rail (45), and the pushing member (43) is connected to the sliding block.

5. A loading buffer according to any of claims 1 to 4, wherein the buffer mechanism (40) further comprises a third driving member (46), the third driving member (46) being capable of driving the second blocking member (42) to reciprocate in the second direction to cause the second blocking member (42) to approach and block the discharge opening of the arc-shaped buffer or to cause the second blocking member (42) to leave the discharge opening of the arc-shaped buffer.

6. A charge buffer according to claim 5, characterized in that the third drive member (46) is a pneumatic cylinder, a hydraulic cylinder or an electric push rod.

7. The temporary feeding storage device according to claim 1, wherein the material guiding and blocking mechanism (30) further comprises a material guiding limiting plate (34), and the material guiding limiting plate (34) is covered on the top of the material guiding chute.

8. A loading buffer as in claim 1, wherein the material guiding and stopping mechanism (30) further comprises a first guiding assembly, the first guiding assembly comprises a movable block (35) and a guiding rod (36), the guiding rod (36) extends along the first direction; the movable block (35) is sleeved on the guide rod (36) and connected with the material guide and the material stopping seat (31), the first driving piece (32) can drive the movable block (35) to drive the material guide and the material stopping seat (31) to move along the guide rod (36) in a reciprocating mode.

9. A charge buffer according to claim 1, 7 or 8, characterized in that the first drive member (32) is a pneumatic cylinder, a hydraulic cylinder or an electric push rod.

10. A feeding buffer device according to claim 1, wherein the detecting mechanism comprises a plurality of optical fiber sensors (51), the optical fiber sensors (51) are uniformly spaced along the circumference of the arc-shaped buffer slot, and the gap between two adjacent optical fiber sensors (51) is smaller than the minimum length of the material.

Images