CN110654032A - Knocking type safe and labor-saving particle supplementing clamp - Google Patents

Abstract

The invention relates to the technical field of light-emitting diodes (LEDs), in particular to a knocking type safe and labor-saving particle supplementing clamp, wherein a floating round wire spring is sleeved on a cylinder at the lower end of a floating forced extrusion part, the upper end of the floating round wire spring abuts against the bottom surface of a boss at the upper end of the floating forced extrusion part, and the lower end of the floating round wire spring abuts against the upper surface of a second middle support; the extrusion end at the lower end of the buoyancy lifting forced extrusion part is movably arranged in the second middle bracket in a penetrating way up and down; the particle positioning piece is arranged below the extrusion end at the lower end of the buoyancy forced extrusion part and is arranged in the particle placing part, the particle placing part is embedded in the first lower bracket, and the particle placing part knocking hole is formed in the second lower bracket below the particle placing part in an up-and-down penetrating mode. The floating forced extrusion part is knocked in sequence through the knocking column, so that materials on the support framework are forcibly extruded into the support by the floating forced extrusion part, the effect of particle supplement is achieved, the safety performance is high, and the labor is saved.

Description

Knocking type safe and labor-saving particle supplementing clamp

Technical Field

The invention relates to the technical field of LEDs (light emitting diodes), in particular to a knocking type safe and labor-saving particle supplementing clamp.

Background

With the development and progress of society, the LED lamp is popularized in the life of people. The front end of the LED lamp, namely the bracket, is one of the important main components of the LED lamp. With the development of the LED industry, the demand on the bracket is increasing day by day, and the bracket production mold develops from dozens of original cavities to hundreds of cavities or even thousands of cavities today, so that bracket particles are generated frequently. Old formula is mended granule tool and is heavy, and it is inconvenient to mend the granule to use old formula for a long time and mend granule tool, operating personnel's hand and foot are aching, still easily press in the operation process in hand, and the security performance is not high, awaits urgent need the improvement.

Disclosure of Invention

The invention aims to provide a reasonably designed knocking type safe and labor-saving particle supplementing clamp, which can knock the buoyancy lifting forced extrusion parts in sequence through a knocking column, so that materials on a support framework are forcibly extruded into a support by the buoyancy lifting forced extrusion parts, the effect of supplementing particles is achieved, the safety performance is high, and more labor is saved.

In order to achieve the purpose, the invention adopts the following technical scheme: the device comprises a clamp framework, a knocking column, a buoyancy lifting forced extrusion part, a buoyancy lifting round wire spring, a guide column, a particle positioning piece and a particle placing piece; the fixture framework comprises an upper bracket, a first middle bracket, a second middle bracket, a first lower bracket and a second lower bracket which are sequentially arranged from top to bottom; the upper bracket, the first middle bracket and the second middle bracket are connected and fixed by a countersunk head screw rod, the first lower support and the second lower support are fixedly connected by a countersunk head screw rod, the second middle support is movably arranged above the first lower support, the guide post is vertically arranged in the first middle bracket, the second middle bracket, the first lower bracket and the second lower bracket in a penetrating way, the upper end of the knocking post is exposed on the upper surface of the upper bracket, the lower end of the floating forced extrusion part movably penetrates through the upper bracket and then is arranged at the upper end of the floating forced extrusion part in an abutting mode, the floating forced extrusion part is movably arranged in a groove body formed in the adjacent surface of the upper bracket and the first middle bracket up and down, a floating round wire spring is sleeved on a cylinder body at the lower end of the floating forced extrusion part, the upper end of the upper support is abutted against the bottom surface of a boss at the upper end of the floating forced extrusion part, and the lower end of the upper support is abutted against the upper surface of the second middle support; the extrusion end at the lower end of the buoyancy lifting forced extrusion part is movably arranged in the second middle bracket in a penetrating way up and down; the particle positioning piece is arranged below the extrusion end at the lower end of the buoyancy forced extrusion part and is arranged in the particle placing part, the particle placing part is embedded in the first lower bracket, and the particle placing part knocking hole is formed in the second lower bracket below the particle placing part in an up-and-down penetrating mode.

Furthermore, a positioning pin penetrates through the first middle support and the second middle support up and down.

The working principle of the invention is as follows: placing LED particles needing particle supplement in a particle placing piece in advance, positioning the LED particles needing particle supplement by using a particle positioning piece in the particle placing piece, lifting a second middle support, placing a particle material in an embedding groove formed in the upper surface of the first lower support, applying a knocking force to the top of a knocking column by using an external force, pressing down the knocking column at the moment, pressing down and lifting to forcibly extrude the part, so that an extruding end at the lower end of the part is forcedly extruded in a floating mode to descend, and extruding the particle material positioned below the part into the particles to be supplemented; after the process is finished, the part is forcedly extruded by the buoyancy lift and ascends under the resilience force of the buoyancy lift round wire spring to reset, and then the next particle waiting link is entered.

After adopting the structure, the invention has the beneficial effects that: the invention provides a knocking type safe and labor-saving particle supplementing clamp, which is characterized in that a knocking column is used for knocking buoyancy lifting forced extrusion parts in sequence, so that materials on a support framework are forcibly extruded into a support by the buoyancy lifting forced extrusion parts, the effect of supplementing particles is achieved, the safety performance is high, and more labor is saved.

Description of the drawings:

fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a right side view of fig. 1.

Fig. 3 is a top view of fig. 1.

Fig. 4 is an enlarged view of a portion a in fig. 2.

Description of reference numerals:

the device comprises a clamp framework 1, an upper support 1-1, a first middle support 1-2, a second middle support 1-3, a first lower support 1-4, a second lower support 1-5, an embedded groove 1-6, a knocking column 2, a buoyancy lifting forced extrusion part 3, a buoyancy lifting circular wire spring 4, a positioning pin 5, a guide pillar 6, a particle positioning part 7, a particle placing part 8, a particle placing part knocking hole 9 and a particle material 10.

The specific implementation mode is as follows:

the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1 to 4, the following technical solutions are adopted in the present embodiment: the device comprises a clamp framework 1, a knocking column 2, a buoyancy lifting forced extrusion part 3 (made of high-strength metal), a buoyancy lifting round wire spring 4, a guide column 6, a particle positioning part 7 and a particle placing part 8; the fixture framework 1 comprises an upper support 1-1, a first middle support 1-2, a second middle support 1-3, a first lower support 1-4 and a second lower support 1-5 which are sequentially arranged from top to bottom; the upper support 1-1, the first middle support 1-2 and the second middle support 1-3 are fixedly connected through a countersunk screw, positioning pins 5 (the first middle support 1-2 and the second middle support 1-3 are conveniently and quickly installed and can smoothly move up and down) are inserted into the first middle support 1-2 and the second middle support 1-3 in a penetrating manner, the first lower support 1-4 and the second lower support 1-5 are fixedly connected through the countersunk screw, the second middle support 1-3 is movably arranged above the first lower support 1-4, the two guide posts 6 are symmetrically arranged in the first middle support 1-2, the second middle support 1-3, the first lower support 1-4 and the second lower support 1-5 in a penetrating manner from top to bottom (the upper support 1-1 is convenient to facilitate the upper support 1-1, the second middle support 1-2, the second middle support 1-3, the first lower support 1-4 and the second lower support 1-5 in a penetrating manner that the upper, Quick installation of a first middle support 1-2, a second middle support 1-3, a first lower support 1-4 and a second lower support 1-5); the upper end of the knocking column 2 is exposed on the upper surface of the upper support 1-1, the lower end of the knocking column movably penetrates through the upper support 1-1 and then is abutted against the upper end of the buoyancy lifting forced extrusion part 3, the buoyancy lifting forced extrusion part 3 is movably arranged in a groove body formed in the adjacent surface of the upper support 1-1 and the first middle support 1-2 up and down, the buoyancy lifting round wire spring 4 is sleeved on a cylinder body at the lower end of the buoyancy lifting forced extrusion part 3, the upper end of the buoyancy lifting forced extrusion part 3 abuts against the bottom surface of an upper end boss of the buoyancy lifting forced extrusion part 3, and the lower end of the buoyancy lifting forced extrusion part 3 abuts against the upper surface; the extrusion end at the lower end of the buoyancy lifting forced extrusion part 3 is movably arranged in the second middle bracket 1-3 in a penetrating way up and down; a particle positioning piece 7 is arranged below an extrusion end at the lower end of the buoyancy-rising forced extrusion part 3, the particle positioning piece 7 is arranged in a particle placing piece 8, the particle placing piece 8 is embedded in a first lower support 1-4, a particle placing piece knocking hole 9 is formed in a second lower support 1-5 below the particle placing piece 8 in a vertically penetrating mode, the particle placing piece knocking hole 9 extends into the particle placing piece knocking hole 9 by utilizing columnar structures such as ejector rods, the particle placing piece 8 is bound out, and therefore the purpose of replacing the particle placing piece 8 is achieved (between replacement, the second middle support 1-3 is removed from the first lower support 1-4).

The working principle of the specific embodiment is as follows: placing LED particles needing particle supplement in a particle placing part 8 in advance, positioning the LED particles needing particle supplement by using a particle positioning part 7 in the particle placing part 8, lifting a second middle support 1-3, placing a particle material 9 in an embedded groove 1-6 formed in the upper surface of a first lower support 1-4, applying a knocking force to the top of a knocking column 2 by using an external force, pressing down the knocking column 2 at the moment, pressing down a floating forced extrusion part 3, and lowering an extrusion end at the lower end of the floating forced extrusion part 3 (the lower surface of a boss at the upper end of the floating forced extrusion part 3 is mutually abutted with a boss groove formed in the upper surface of the first middle support 1-2 and used for limiting the sinking position of the floating forced extrusion part 3), and extruding a particle material 10 positioned below the floating forced extrusion part into the particles to be supplemented; after the process is finished, the buoyancy forced extrusion part 3 rises and resets under the resilience force of the buoyancy circular wire spring 4 (the upper surface of the boss at the lower end of the knocking column 2 is mutually supported with the boss groove formed in the lower surface of the upper support 1-1 and used for limiting the resetting of the buoyancy forced extrusion part 3 and the knocking column 2), and then the next particle link to be compensated is entered.

After adopting above-mentioned structure, this embodiment's beneficial effect is:

1. the floating forced extrusion parts are knocked by the knocking column in sequence, so that the problem of labor force brought to operators due to long-time manual particle supplement is avoided, and the aim of saving labor is fulfilled;

2. by means of the positioning pin 5, the operation smoothness of the buoyancy-lifting forced extrusion part is effectively improved, and the particle supplementing accuracy is improved;

3. the buoyancy lifting forced extrusion part 3 returns under the resilience of the buoyancy lifting circular wire spring 4 to prepare for the next particle supplementing process, and the particle supplementing efficiency is improved.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims (3)

1. The utility model provides a laborsaving benefit granule anchor clamps of percussive safety which characterized in that: the device comprises a clamp framework (1), a knocking column (2), a buoyancy lifting forced extrusion part (3), a buoyancy lifting round wire spring (4), a guide pillar (6), a particle positioning piece (7) and a particle placing piece (8); the fixture framework (1) comprises an upper support (1-1), a first middle support (1-2), a second middle support (1-3), a first lower support (1-4) and a second lower support (1-5) which are sequentially arranged from top to bottom; the upper support (1-1), the first middle support (1-2) and the second middle support (1-3) are fixedly connected through a countersunk screw, the first lower support (1-4) and the second lower support (1-5) are fixedly connected through a countersunk screw, the second middle support (1-3) is movably arranged above the first lower support (1-4), and the guide pillar (6) vertically penetrates through the first middle support (1-2), the second middle support (1-3), the first lower support (1-4) and the second lower support (1-5); the upper end of the knocking column (2) is exposed on the upper surface of the upper support (1-1), the lower end of the knocking column movably penetrates through the upper support (1-1) and then is abutted against the upper end of the buoyancy lifting forced extrusion part (3), the buoyancy lifting forced extrusion part (3) is movably arranged in a groove body formed in the adjacent surface of the upper support (1-1) and the first middle support (1-2) up and down, a buoyancy lifting round wire spring (4) is sleeved on a cylinder body at the lower end of the buoyancy lifting forced extrusion part (3), the upper end of the buoyancy lifting forced extrusion part is abutted against the bottom surface of an upper end boss of the buoyancy lifting forced extrusion part (3), and the lower end of the buoyancy lifting forced extrusion part is abutted against the upper surface of the second middle support (1; the extrusion end at the lower end of the buoyancy lifting forced extrusion part (3) is movably arranged in the second middle bracket (1-3) in a penetrating way up and down; a particle positioning piece (7) is arranged below an extrusion end at the lower end of the buoyancy forced extrusion part (3), the particle positioning piece (7) is arranged in a particle placing piece (8), the particle placing piece (8) is embedded in a first lower support (1-4), and a particle placing piece knocking hole (9) is formed in a second lower support (1-5) below the particle placing piece (8) in a vertically penetrating mode.

2. The knock-type safe and labor-saving particle supplementing clamp as claimed in claim 1, wherein: the first middle support (1-2) and the second middle support (1-3) are inserted with positioning pins (5) in a vertical penetrating manner.

3. The knock-type safe and labor-saving particle supplementing clamp as claimed in claim 1, wherein: the working principle is as follows: placing LED particles needing particle supplement in a particle placing part (8) in advance, positioning the LED particles needing particle supplement by using a particle positioning part (7) in the particle placing part (8), lifting a second middle bracket (1-3), placing a particle material (10) in an embedding groove (1-6) formed in the upper surface of a first lower bracket (1-4), applying a knocking force to the top of a knocking column (2) by using an external force, pressing down the knocking column (2), pressing down a buoyancy lifting forced extrusion part (3), enabling an extrusion end at the lower end of the buoyancy lifting forced extrusion part (3) to descend, and extruding the particle material (10) positioned below the buoyancy lifting forced extrusion part into the particles to be supplemented; after the process is finished, the buoyancy lifting forced extrusion part (3) rises and resets under the resilience force of the buoyancy lifting round wire spring (4), and then the next particle waiting compensation link is carried out.

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