CN108272189B - Rapid small particle loading device and method - Google Patents

Abstract

According to the small particle fast loading device and the method for loading small particles, the small particle fast loading device is provided with a particle discharging unit which comprises a slideway with a U-shaped cross section, a transverse groove is arranged on the inner bottom surface, a groove bottom through hole is arranged in the middle of the groove, sliding grooves are respectively arranged on two inner side surfaces, a plurality of particle discharging pieces are provided with an inlet end and an outlet end which are communicated, the particle discharging pieces are arranged at the bottom of the groove, the inlet end is communicated with the groove bottom through hole, a pressing unit is arranged above the slideway and comprises a sliding plate which is arranged in the sliding groove and slides in the sliding groove, the sliding plate is also provided with a through hole which is coaxial with the inlet end, the particulate matter discharge is provided with and is used for the flexure strip of little particulate matter card in the particulate matter discharge, and little particulate matter forces down to make the flexure strip warp and pass through the exit end under pressing of pressing the piece. The small particle rapid loading device has the characteristics of rapidly positioning the small particle loading and improving the operation efficiency.

Description

Rapid small particle loading device and method

Technical Field

The invention relates to a loading device and an assembling method, in particular to a small particle rapid loading device and a small particle loading method.

Background

At present, people pursue more and more for the decoration of clothes and daily necessities, the tiny glass diamond particles on the ornaments have larger difficulty in inlaying due to different sizes and shapes, and the glass diamond is sucked by a suction needle and inlaid on the ornaments one by one. Such inlay mounting means, it is slow, inefficient, moreover to operator's eyes injury great to make the cost of labor higher.

Disclosure of Invention

The present invention is made to solve the above problems, and an object of the present invention is to provide a small particle rapid loading device and a method for loading small particles, which are used to rapidly position the loading of small particles and improve the operation efficiency.

The invention provides a small particulate matter rapid loading device, which is used for rapidly loading solid small particulate matters on a target object, and comprises a particulate matter discharging unit and a pressing unit, wherein the particulate matter discharging unit is used as a channel for accommodating and discharging the small particulate matters onto the target object, the pressing unit is used for pressing the small particulate matters, and the device is characterized in that: the particulate matter discharge unit includes: the cross section of the slideway is U-shaped, the slideway is provided with an inner bottom surface and two opposite inner side surfaces, a plurality of transverse grooves which are longitudinally arranged are arranged on the inner bottom surface, a groove bottom through hole is arranged in the middle of each groove, each groove is used for containing small particles, and sliding grooves which are equal in height and run through the two ends of the slideway are respectively arranged on the two inner side surfaces in parallel; a plurality of particulate matter discharge spare, entry end and exit end that are linked together have, the setting is in the recess bottom, the entry end is linked together with the tank bottom through-hole, the internal diameter of entry end is greater than the width of little particulate matter, the exit end contacts with the target object, a plurality of reference columns, the reference column is cylindricly, the one end setting of reference column just is located the below of spout on an medial surface of slide, other end perpendicular to spout extends along bottom surface width direction, the equal height of reference column sets up and the interval between two adjacent reference columns is the same, press the unit, the setting is in the slide top, include: the sliding plate is arranged in the sliding groove and slides in the sliding groove, and a through hole coaxial with the inlet end is further formed in the sliding plate; the pressing piece is arranged in the through hole and used for pressing the small particles, the particle discharging piece is also provided with an elastic sheet used for clamping the small particles in the particle discharging piece, and the small particles are pressed by the pressing piece to deform the elastic sheet so that the small particles pass through the outlet end; the positioning pin is arranged in the positioning through hole of the sliding plate, and the sliding plate is provided with the positioning through hole corresponding to the positioning column; the positioning pin spring is sleeved on the positioning pin, and the upper end of the positioning pin spring is in contact with the bottom surface of the sliding plate and is used for reciprocating the positioning pin when the sliding plate slides; the finger pressing plate is arranged at the top of the pressing piece; the compression spring is arranged on the pressing piece, the upper end of the compression spring is contacted with the bottom surface of the finger-pressing piece, and the lower end of the compression spring is contacted with the surface of the sliding plate and used for reciprocating the finger-pressing piece; and the baffle plate is parallel to the pressing piece and is perpendicular to the slide way and arranged at one end of the slide plate.

In the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: the pressing unit further comprises a check ring which is arranged on the locating pin, is in contact with the lower end of the spring and is used for restraining the spring.

In addition, in the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: the pressing unit also comprises a plurality of finger pressing plate pins, and the finger pressing plate pins are vertically and fixedly connected with the lower surface of the finger pressing plate; and the plurality of cylindrical through holes are arranged on the sliding plate corresponding to the finger-pressure plate pins, and the finger-pressure plate penetrates through the cylindrical through holes through the finger-pressure plate pins for positioning.

In addition, in the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: wherein the upper surface of the acupressure probe is rough.

In addition, in the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: one end of the baffle is in movable contact with the sliding plate and can slide up and down relative to the sliding plate, and the other end of the baffle is in contact with the inner bottom surface and is used for distributing small particles into the groove when the sliding plate slides.

In addition, in the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: wherein, the pressing piece is in a rod shape with one large end and one small end, and the cross section of the rod gradually decreases from the rod body to the end part.

In addition, in the small particulate matter rapid loading device provided by the invention, the device can also have the following characteristics: wherein, particulate matter discharge spare formula shell fragment structure as an organic whole is the cone tube-shape.

The invention provides a method for loading small particles by using any one of the small particle rapid loading devices, which is characterized by comprising the following steps:

step 1, pushing a sliding plate to the foremost end of a slideway, and placing small particles into the front end of the slideway;

step 2, holding the slide way by one hand, pressing the finger-pressing plate by the thumb of the other hand to move the pressing unit backwards under the action of friction force, and moving small particles backwards under the action of the baffle plate so that a part of small particles fall into the inlet end of the particle discharging piece at the bottom end of the groove through the through hole at the bottom of the groove;

step 3, when the sliding plate moves, fingers obviously feel the resistance of a positioning pin on the sliding plate under the blocking of a positioning column on the side surface of the U-shaped groove, and at the moment, the pressing piece is just positioned above a through hole at the bottom of the groove;

step 4, aligning the outlet end with a target object, pressing the finger-pressing plate, and allowing small particles to fall from the particle discharging part to the target object under the pressure of the pressing part;

step 5, loosening the finger-pressing plate, and enabling the pressing piece to be restored to the original position under the action of the compression spring;

step 6, pushing the pressing unit by hand to move backwards continuously, wherein the positioning pin can move upwards under the blocking of the positioning column and can be restored to the original position under the action of a positioning pin spring when sliding through the positioning column;

and 7, repeating the steps 1-6, and carrying out the next assembly.

Action and Effect of the invention

According to the small particulate matter rapid loading device and the method for loading small particulate matter of the present invention, the small particulate matter rapid loading device comprises: a particulate matter discharge unit comprising: a slideway with a U-shaped cross section, a transverse groove arranged on the inner bottom surface, a through hole at the bottom of the groove arranged in the middle of the groove, a chute arranged on two inner side surfaces, a plurality of particle discharging pieces with an inlet end and an outlet end communicated with each other and arranged at the bottom of the groove, a pressing unit arranged above the slideway and comprising a sliding plate arranged in the chute and sliding in the chute, a through hole coaxial with the inlet end arranged on the sliding plate, and a pressing piece arranged in the through hole, the particle discharging piece is provided with an elastic sheet for clamping small particles in the particle discharging piece, the small particles are pressed by the pressing piece to deform the elastic sheet so that the small particles pass through the outlet end, therefore, the small particle rapid loading device has the characteristics of rapidly positioning the small particle loading and improving the operation efficiency.

Drawings

FIG. 1 is a schematic perspective view of a rapid small particle loading device according to an embodiment of the present invention;

FIG. 2 is a schematic perspective view of a particulate matter discharge unit in an embodiment of the invention;

FIG. 3 is a schematic top view of a particulate matter discharge unit in an embodiment of the invention;

FIG. 4 is a schematic side view of a rapid small particle loading device according to an embodiment of the present invention;

FIG. 5 is a schematic view of an integrated particulate matter discharging member of the small particulate matter rapid loading device according to an embodiment of the present invention;

fig. 6 is a schematic perspective view of a pressing unit in an embodiment of the present invention; and

FIG. 7 is a perspective view of a locating pin in an embodiment of the present invention.

Detailed Description

In order to make the technical means, the creation features, the achievement objects and the effects of the present invention easy to understand, the following embodiments are specifically described with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view of a rapid small particle loading device according to an embodiment of the present invention;

as shown in fig. 1, the small granule rapid loading device 100 has a granule discharging unit 10 and a pressing unit 20.

FIG. 2 is a schematic perspective view of a particulate matter discharge unit in an embodiment of the invention;

fig. 3 is a schematic top view of a particulate matter discharge unit in an embodiment of the invention.

As shown in fig. 2 and 3, the particle discharging unit 10 includes a chute 11, a groove 12, a chute 13, a positioning column 14, and a particle discharging member 15.

The cross section of the slideway 11 is U-shaped, and has an inner bottom surface 111 and two opposite inner side surfaces, namely a first inner side surface 112 and a second inner side surface 113, wherein the second inner side surface 113 is inclined, so that an operator can observe a target object conveniently, and the cross section in the embodiment is similar to U-shaped.

The inner bottom surface 111 is provided with 19 transverse grooves 12 uniformly arranged along the longitudinal direction, the two ends of each groove 12 are higher than the middle part, and the middle part of each groove 12 is provided with a groove bottom through hole 121.

The first inner side surface 112 and the second inner side surface 113 are respectively provided with two sliding chutes 13 which have the same height and penetrate through two ends of the sliding way in parallel.

The positioning columns 14 are cylindrical, the number of the positioning columns is 19 in the embodiment, the positioning columns are uniformly arranged along the longitudinal direction, are in a straight line and are arranged at the same height below the sliding chute 13, one end of each positioning column 14 is perpendicular to the sliding chute 13 and is fixedly connected with the inner side surface 112 of the sliding chute 11, and the other end of each positioning column is a free end.

FIG. 4 is a schematic side view of a rapid small particle loading device according to an embodiment of the present invention;

FIG. 5 is a schematic view of an integrated particle ejector of the rapid small particle loading device according to an embodiment of the present invention.

As shown in fig. 4 and 5, the plurality of particle discharging members 15 are arranged in a straight line corresponding to the plurality of groove bottom through holes 121 and are disposed at the bottom of the groove 12. The particulate discharging member 15 has a cone shape having an inlet end 151 and an outlet end 152 communicating with each other. The inlet end 151 corresponds to and communicates with the groove bottom through hole 121, and the outlet end 152 has 4 open grooves. The particulate matter discharging member 15 in this embodiment is of an integrated structure, and the number thereof is 19.

Fig. 6 is a schematic perspective view of a pressing unit in an embodiment of the present invention.

As shown in fig. 6, the pressing unit 20 includes a slide plate 21, a pressing piece 22, a positioning pin 23, a spring 24, a retainer ring 25, a finger plate 26, a compression spring 27, a finger plate pin 28, and a stopper 29.

The slide plate 21 has a rectangular shape, is disposed in the slide groove 13 and slides in the slide groove 13, and has four holes. Three cylindrical through holes are arranged on the diagonal of the sliding plate 21: the center of the diagonal line is a central through hole which is coaxial with the inlet end 151; the other two are the platen positioning holes, which are located at the upper left and lower right of the slide plate 21, respectively, as shown in fig. 6. A positioning through hole is further formed in the lower left of the slide plate 21, and the positioning through hole is provided corresponding to the positioning post 14 for engagement positioning.

A pressing piece 22 is arranged in the central through hole for pressing the small granules. The pressing piece 22 is in a rod shape with one large end and one small end, the cross section of the rod is gradually reduced from the rod body to the end part, and the material of the pressing piece 22 is metal.

FIG. 7 is a perspective view of a locating pin in an embodiment of the present invention.

As shown in fig. 7, the positioning pin 23 has a top cover at its top end and an arc-shaped bottom end, and the positioning pin 23 is disposed in the positioning through hole of the slide plate 21.

The spring 24 is sleeved on the positioning pin 23, and the upper end of the spring 24 is contacted with the bottom surface of the sliding plate 21.

A retainer ring 25 is provided on the positioning pin 23 and contacts the lower end of the spring 24 for restraining the spring 24.

When the sliding plate 21 slides back and forth in the sliding chute 13, the positioning pin 23 moves up and down under the action of the positioning column 14 and the compression spring 24, and when the positioning pin 23 falls, the sliding plate 21 is positioned once.

An acupressure plate 26 is provided on the top of the pressing member 22, and the upper surface is provided to be rough. In this embodiment, the finger-pressure plate 26 is made of metal, the finger-pressure plate 26 is connected to the pressing member 22 by welding, and metal strips arranged in sequence are welded to the upper surface of the finger-pressure plate 26, and the strips serve to increase friction between the finger and the finger-pressure plate 26.

The compression spring 27 and the spring washer are installed on the pressing member 22, the upper end of the compression spring 27 contacts the bottom surface of the finger-pressure plate 26, the lower end of the compression spring 27 contacts the spring washer, the spring washer contacts the upper surface of the sliding plate 21, and the pressing member 22 can reciprocate up and down by the elastic force generated by the compression spring 27.

The 2 finger-pressure plate pins 28 are respectively arranged corresponding to the 2 finger-pressure plate positioning holes, one end of each finger-pressure plate pin 28 is vertically and fixedly connected with the lower surface of the finger-pressure plate 26, the other end of each finger-pressure plate pin 28 penetrates through the finger-pressure plate positioning holes, and the finger-pressure plate 26 is positioned by the finger-pressure plate pins 28 penetrating through the finger-pressure plate positioning holes.

The baffle plate 29 is arranged at one end, namely the rear end, far away from the positioning pin 23 on the sliding plate 21, the rear end of the sliding plate 21 is provided with a long through hole, the baffle plate 29 is parallel to the pressing piece 22 and is perpendicular to the sliding groove 13 and is arranged in the long through hole, the baffle plate 29 is in movable contact with the sliding plate 21 in the long through hole, the baffle plate 29 can slide up and down relative to the sliding plate 21, one end of the baffle plate 29, after penetrating through the long through hole, is in contact with the inner bottom surface 111, when the sliding plate 21 slides back and forth in the sliding groove 13, the baffle plate 29 moves up and down along with the convex-concave degree of the groove surface, and the function of the baffle plate is to pull back small particles in the groove 12, so that one small particle.

The small particulate matter rapid loading device comprises the following operation steps:

the operator pushes the slide plate 21 to the front end of the chute 11, puts the small particles, i.e. the glass diamond, into the front end of the chute 11, holds the small particles fast loading device 100 with one hand, presses the finger-hold plate 26 with the thumb of the other hand to move the pressing unit 20 backwards under the action of friction, the glass diamond moves backwards under the action of the baffle plate 29, and a part of the glass diamond falls into the tapered hole of the particle discharging member 15 at the bottom end of the U-shaped chute through the through hole 121. When the sliding plate 21 moves, the finger can obviously feel the resistance of the positioning pin 23 on the sliding plate 21 under the blocking of the positioning column 14 on the side surface of the U-shaped groove, and at the moment, the pressing piece 22 is just above the through hole 121 on the bottom of the groove. The operator presses the finger plate 26 with the taper hole aligned with the target object, the glass diamond falls down from the particle discharging member 15 to the target object under the pressure of the pressing member 22, and the pressing member 22 is restored to the original position under the action of the compression spring 27 by releasing the finger plate 26; the operator pushes the pressing unit 20 to move backward, and the positioning pin 23 moves upward under the stop of the positioning post 14, and when sliding over the positioning post 14, it returns to the original position under the action of the spring, and then performs the next assembly.

Effects and effects of the embodiments

According to the small particle thing quick loading device of this embodiment, because have: a particulate matter discharge unit comprising: a slideway with a U-shaped cross section, a transverse groove arranged on the inner bottom surface, a through hole at the bottom of the groove arranged in the middle of the groove, a chute arranged on two inner side surfaces, a plurality of particle discharging pieces with an inlet end and an outlet end communicated with each other and arranged at the bottom of the groove, a pressing unit arranged above the slideway and comprising a sliding plate arranged in the chute and sliding in the chute, a through hole coaxial with the inlet end arranged on the sliding plate, and a pressing piece arranged in the through hole, the particle discharging piece is provided with an elastic sheet for clamping small particles in the particle discharging piece, the small particles are pressed by the pressing piece to deform the elastic sheet so that the small particles pass through the outlet end, therefore, the small particle rapid loading device has the characteristics of rapidly positioning the small particle loading and improving the operation efficiency.

In addition, the upper surface of the finger-pressing plate is rough, so that the friction force between fingers and the finger-pressing plate is increased, and the force is conveniently applied when an operator pushes the finger-pressing plate.

Furthermore, the particle discharge unit further comprises a plurality of positioning columns, the pressing unit further comprises positioning pins, and when the positioning pins on the sliding plate are blocked and positioned by the positioning columns, the pressing pieces just aim at the through holes in the bottom of the groove, so that the assembly is quicker and more accurate.

Still further, the pressing unit further includes a compression spring for reciprocating the pressing member at the time of pressing, thereby improving assembling efficiency.

Furthermore, the particle discharging unit is of an integrated structure, can be manufactured in a large scale through die forming, and is easy to process and low in cost.

Claims (8)

1. A small particle rapid loading device for rapidly loading solid small particles on a target object, comprising a particle discharge unit as a passage for accommodating and discharging the small particles onto the target object, and a pressing unit for pressing the small particles, characterized in that:

the particulate matter discharge unit includes:

the cross section of the slideway is U-shaped, the slideway is provided with an inner bottom surface and two opposite inner side surfaces, a plurality of transverse grooves which are longitudinally arranged are arranged on the inner bottom surface, a groove bottom through hole is arranged in the middle of each groove, each groove is used for accommodating the small particles, and sliding grooves which are equal in height and run through the two ends of the slideway are respectively arranged on the two inner side surfaces in parallel;

the particle discharging pieces are provided with an inlet end and an outlet end which are communicated, the inlet end and the outlet end are arranged at the bottom of the groove, the inlet end is communicated with the through hole at the bottom of the groove, the inner diameter of the inlet end is larger than the width of the small particles, and the outlet end is contacted with the target object;

a plurality of positioning columns which are cylindrical, one end of each positioning column is arranged on one inner side surface of the slide way and is positioned below the slide way, the other end of each positioning column is perpendicular to the slide way and extends along the width direction of the bottom surface, the positioning columns are arranged at equal heights, and the intervals between every two adjacent positioning columns are the same,

the pressing unit is arranged above the slide way and comprises:

the sliding plate is arranged in the sliding groove and slides in the sliding groove, and a through hole which is coaxial with the inlet end is further formed in the sliding plate;

the pressing piece is arranged in the through hole and is used for pressing the small particles;

the positioning pin is arranged in the positioning through hole of the sliding plate, and the sliding plate is provided with the positioning through hole corresponding to the positioning column;

the positioning pin spring is sleeved on the positioning pin, the upper end of the positioning pin spring is in contact with the bottom surface of the sliding plate, and the positioning pin spring is used for reciprocating the positioning pin when the sliding plate slides;

the finger pressing plate is arranged at the top of the pressing piece;

the compression spring is arranged on the pressing piece, the upper end of the compression spring is in contact with the bottom surface of the finger-pressure plate, and the lower end of the compression spring is in contact with the surface of the sliding plate and is used for reciprocating the pressing piece;

a baffle plate which is parallel to the pressing piece and is perpendicular to the slide way and is arranged at one end of the slide plate,

the particle discharging piece is further provided with an elastic sheet used for clamping the small particles in the particle discharging piece, and the small particles are pressed by the pressing piece to deform the elastic sheet so that the small particles pass through the outlet end.

2. The small particle rapid loading device of claim 1, wherein:

wherein the pressing unit further includes:

and the retainer ring is arranged on the positioning pin, is in contact with the lower end of the positioning pin spring and is used for restraining the positioning pin spring.

3. The small particle rapid loading device of claim 1, wherein:

wherein the pressing unit further includes:

the finger pressing plate pins are vertically and fixedly connected with the lower surface of the finger pressing plate;

and the plurality of cylindrical through holes are arranged on the sliding plate corresponding to the finger-pressing plate pins, and the finger-pressing plate penetrates through the cylindrical through holes through the finger-pressing plate pins to be positioned.

4. The small particle rapid loading device of claim 1, wherein:

wherein the upper surface of the acupressure probe is rough.

5. The small particle rapid loading device of claim 1, wherein:

wherein one end of the baffle is in movable contact with the sliding plate and can slide up and down relative to the sliding plate, and the other end of the baffle is in contact with the inner bottom surface and is used for distributing the small particles into the groove when the sliding plate slides.

6. The small particle rapid loading device of claim 1, wherein:

the pressing piece is in a rod shape with one large end and one small end, and the cross section of the rod is gradually reduced from the rod body to the end part of the rod with the small end.

7. The small particle rapid loading device of claim 1, wherein:

wherein, particulate matter discharge spare formula shell fragment structure as an organic whole is the cone tube-shape.

8. A method for loading small particles by using the small particles rapid loading device according to any one of claims 1 to 7, comprising the steps of:

step 1, pushing the sliding plate to the foremost end of the slideway, and placing the small particles into the front end of the slideway;

step 2, holding the slide way by one hand, pressing the finger-pressing plate by a thumb of the other hand to move the pressing unit backwards under the action of friction force, and moving the small particles backwards under the action of the baffle plate so that a part of the small particles fall into the inlet end of the particle discharging piece at the bottom end of the groove through the through hole at the bottom of the groove;

step 3, when the sliding plate moves, fingers obviously feel the resistance of the positioning pin on the sliding plate under the blocking of the positioning column on the inner side surface of the sliding way, and at the moment, the pressing piece is just positioned above the through hole at the bottom of the sliding way;

step 4, aligning the outlet end with the target object and pressing down the finger-pressing plate, so that the small particles can fall from the particle discharging part to the target object under the pressure of the pressing part;

step 5, loosening the finger-pressing plate, and enabling the pressing piece to be restored to the original position under the action of the compression spring;

step 6, the pressing unit is pushed by a hand to move backwards continuously, the positioning pin can move upwards under the blocking of the positioning column at the moment, and the positioning pin can be restored to the original position under the action of the positioning pin spring when sliding through the positioning column;

and 7, repeating the steps 1-6, and carrying out the next assembly.