CN219619422U - Automatic feeding rail of actuator - Google Patents

Abstract

An actuator auto-feed track relates to aerosol packaging devices. Comprising the following steps: the inlet slide rail is fixedly arranged on the vibration material arranging mounting plate and is connected with a discharge hole of the vibration plate; the inlet sliding rail is provided with a first sliding groove matched with the actuator; the inlet sliding rail is provided with an air passage I extending along the length direction of the inlet sliding rail, the air passage I is provided with a plurality of inclined air passages I communicated with the sliding groove I, and the inclined air passages extend towards the sliding direction of the actuator; the head part of the outlet slide rail is fixedly connected with the inlet slide rail, and the tail part of the outlet slide rail extends to the positioning bottom plate; and a second sliding groove matched with the actuator is formed in the outlet sliding rail. The utility model enables the actuator to stably slide onto the positioning bottom plate and enter the actuator mounting station.

Description

Automatic feeding rail of actuator

Technical Field

The present utility model relates to aerosol packaging devices and, more particularly, to an actuator auto-feed track.

Background

Aerosol refers to a preparation in which a material and a proper propellant are packaged in a pressure-resistant container with a special valve device, and when the aerosol is used, the content is sprayed out into a fine mist, foam or other shapes by the pressure of the propellant in the container. An actuator is mounted on the valve core of the valve for opening the valve of the aerosol.

The aerosol actuator assembly process generally comprises the steps of finishing the disordered stacked actuators after aerosol filling, valve mounting, valve sealing, propellant filling (inflating), weighing and checking, and water bath tightness detection, and orderly outputting and conveying the disordered stacked actuators. Then the aerosol can and the actuator are fed in the same step, and finally the actuator is assembled on the valve core of the aerosol in a buckling or beating mode.

Prior art such as chinese patent grant bulletin nos.: the present utility model disclosed in ZL2012101783902, entitled "actuator guide for automatic pressure actuator machine", relates to an actuator guide for automatic pressure actuator machine. The air inlet actuator comprises an actuator body, an air blowing nozzle, an upper guide plate and a lower guide plate, wherein the actuator body is formed by assembling and welding a bottom plate, a groove drum and a rib plate. The blowing nozzle is fixed on the rib plate, the head of the blowing nozzle is inserted into the groove drum, and the air flow forms thrust to the actuator. There are also linear vibration feeders based on the principle of vibration for actuator feeding.

In the actuator guiding device of the automatic pressure actuator machine in the prior art, the air flow of the blowing nozzle points to the inner cavity of the actuator, the upward component force is large, the actuator is propped up against the upper cover plate, the forward pushing resistance is large, and particularly, the obtained forward pushing force is smaller when the blowing nozzle is positioned between the two actuators in motion; the feeding mode of the linear feeder is adopted, the track is longer, the outlet thrust is smaller, the air nozzle is assisted at the single side or the top of the track for blowing, the conveying efficiency is not very high, the feeding mode is suitable for the stepping feeding mode, if the feeding mode is applied to an actuator high-speed assembly machine with more than 120 cans/min, the problems of material leakage, material clamping and the like caused by insufficient thrust are caused, and the conveying stability cannot be effectively ensured.

Disclosure of Invention

The utility model aims at the problems and provides an actuator automatic feeding track which is exquisite in structure, efficient and stable in conveying.

The technical scheme of the utility model is as follows: an actuator autofeed rail comprising:

the inlet slide rail is fixedly arranged on the vibration material arranging mounting plate and is connected with a discharge hole of the vibration plate; the inlet sliding rail is provided with a first sliding groove matched with the actuator; the inlet sliding rail is provided with an air passage I extending along the length direction of the inlet sliding rail, the air passage I is provided with a plurality of inclined air passages I communicated with the sliding groove I, and the inclined air passages extend towards the sliding direction of the actuator; and

the head part of the outlet slide rail is fixedly connected with the inlet slide rail, and the tail part of the outlet slide rail extends to the positioning bottom plate; and a second sliding groove matched with the actuator is formed in the outlet sliding rail.

The outlet sliding rail is provided with a second air passage extending along the length direction of the outlet sliding rail, the second air passage is provided with a plurality of second inclined air passages communicated with the second sliding groove, and the inclined air passages extend towards the sliding direction of the actuator.

Specifically, an arc-shaped sliding rail which is fixedly connected is arranged between the inlet sliding rail and the outlet sliding rail;

and a sliding groove III matched with the actuator is formed in the arc-shaped sliding rail.

Specifically, a first main air hole is formed in the inlet sliding rail;

and the first main air hole is provided with an extension air passage I communicated with the first air passage.

Specifically, the first air passage is provided with a pair of air passages which are symmetrically arranged on the inlet sliding rail.

Specifically, a second main air hole is formed in the outlet sliding rail;

and the second main air hole is provided with a second extension air passage communicated with the second air passage.

Specifically, the second air passage is provided with a pair of air passages which are symmetrically arranged on the outlet sliding rail.

Specifically, the inlet slide rail is adjustably and fixedly arranged on the vibration material arranging mounting plate through a slide rail bracket.

Specifically, the bottom of the sliding rail bracket is fixedly connected with the vibration material arranging mounting plate, and the top of the sliding rail bracket is provided with a hinge groove;

the bottom of entry slide rail is equipped with the articulated piece that stretches into in the hinge groove, the articulated piece passes through the connecting piece adjustable fixed setting in the hinge groove.

Specifically, a photoelectric sensor which is fixedly connected is arranged at the side part of the outlet sliding rail;

and a detection groove matched with the photoelectric sensor is formed in the outlet sliding rail.

The utility model comprises an inlet slide rail and an outlet slide rail; the inlet sliding rail is fixedly arranged on the vibration material arranging mounting plate and is connected with a discharge hole of the vibration plate; the inlet slide rail is provided with a first air passage extending along the length direction of the inlet slide rail, the first air passage is provided with a plurality of first inclined air passages communicated with the first sliding groove, and the first inclined air passages extend towards the sliding direction of the actuator; the head part of the outlet slide rail is fixedly connected with the inlet slide rail, and the tail part of the outlet slide rail extends to the positioning bottom plate; the actuator in the vibration disc sequentially enters the head end of the inlet slide rail through vibration, the inlet slide rail is arranged, the actuator slides downwards, and the actuator slides downwards continuously in a high-efficiency and stable manner through a pair of first inclined air passages blowing air to the sliding direction of the actuator in the sliding process; the air enters the outlet slide rail after passing through the arc slide rail; a pair of inclined air passages on the outlet slide rail blow air in the sliding direction of the actuator, so that the actuator stably slides onto the positioning bottom plate and enters the actuator mounting station.

Drawings

Figure 1 is a schematic perspective view of the connection state of the feeding track and the positioning bottom plate,

figure 2 is a schematic perspective view of the feed rail,

figure 3 is a top view of the feed rail,

figure 4 is a schematic view of the structure of the first air passage on the inlet slide rail,

figure 5 is a cross-sectional view taken along the direction a in figure 4,

figure 6 is a schematic diagram of the structure of the second air passage on the outlet slide rail,

FIG. 7 is a cross-sectional view taken along the direction B in FIG. 6;

in the drawing, 100 is a vibration material arranging mounting plate, 200 is a positioning bottom plate,

300 is the inlet slide rail, 310 is the first slide rail, 320 is the first air passage, 330 is the first inclined air passage, 340 is the first main air hole, 341 is the first extended air passage,

400 is the outlet slide rail, 410 is the slide way two, 420 is the air way two, 430 is the inclined air way two, 440 is the main air hole two, 441 is the extension air way two, 450 is the detection groove,

500 is an arc-shaped slide rail, 510 is a slide groove III,

600 is a slide rail bracket, 610 is a hinge slot,

700 is a photosensor.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "left", "right", "vertical", "horizontal", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The utility model is shown in fig. 1-7; an actuator autofeed rail comprising:

the inlet slide rail 300 is fixedly arranged on the vibration material arranging mounting plate 100 and is connected with a discharge hole of the vibration plate; the inlet slide rail 300 is provided with a first slide groove 310 matched with the actuator; the inlet slide rail 300 is provided with an air passage I320 extending along the length direction of the inlet slide rail 300, the air passage I320 is provided with a plurality of inclined air passages I330 communicated with the slide groove I310, and the inclined air passages I330 extend towards the sliding direction of the actuator; and

the head of the outlet sliding rail 400 is fixedly connected with the inlet sliding rail 300, and the tail of the outlet sliding rail 400 extends to the positioning bottom plate 200; the outlet slide rail 400 is provided with a second slide groove 410 matched with the actuator; the outlet slide rail 400 is provided with a second air passage 420 extending along the length direction of the outlet slide rail 400, the second air passage 420 is provided with a plurality of second inclined air passages 430 communicated with the second sliding groove 410, and the second inclined air passages 430 extend towards the sliding direction of the actuator.

Further expanding, an arc-shaped sliding rail 500 fixedly connected is arranged between the inlet sliding rail 300 and the outlet sliding rail 400;

the arc-shaped sliding rail 500 is provided with a third sliding groove 510 matched with the actuator. The arc-shaped sliding rail 500 may have a linear structure in addition to the arc-shaped structure, and is connected between the inlet sliding rail 300 and the outlet sliding rail 400.

Further expanding, the inlet sliding rail 300 is provided with a first main air hole 340;

the first main air hole 340 is provided with an extended air channel one 341 communicated with the first air channel 320. The first main air hole 340 is provided with a first throttle valve for controlling the air flow in the first main air hole 340. After passing through the first main air hole 340, the air enters the first extending air passages 341 respectively, so that the synchronous air outlet of the first inclined air passages 330 is ensured.

The first air passages 320 are provided with a pair, and are symmetrically arranged on the inlet slide rail 300.

Further preferably, the inlet sliding rail 300 comprises an inlet lower sliding body and an inlet upper sliding cover which are detachably, sealingly and fixedly connected, and fig. 4-5 are schematic structural views of the inlet lower sliding body, and the first main air hole 340 and the first air channel 320 are respectively arranged on the inlet lower sliding body and sealed by the upper sliding cover. The outlet track is also detachable from top to bottom, which is convenient for the maintenance of the air passage and is beneficial to processing.

Further defined, the outlet sliding rail 400 is provided with a second main air hole 440;

the second main air hole 440 is provided with a second extending air channel 441 connected to the second air channel 420.

The second air passage 420 is provided with a pair of air passages and is symmetrically arranged on the outlet slide rail 400.

Further preferably, the inlet slide rail 300 is adjustably and fixedly arranged on the vibration material arranging mounting plate 100 through a slide rail bracket 600.

The bottom of the sliding rail bracket 600 is fixedly connected with the vibration material arranging mounting plate 100, and the top is provided with a hinge groove 610;

the bottom of the inlet slide rail 300 is provided with a hinge block extending into the hinge groove 610, and the hinge block is adjustably and fixedly arranged in the hinge groove 610 through a connecting piece.

Further preferably, a fixedly connected photoelectric sensor 700 is arranged at the side part of the outlet sliding rail 400;

the outlet slide rail 400 is provided with a detection groove 450 adapted to the photoelectric sensor 700.

The first main air hole 340 is provided with a first throttle valve.

The second main air hole 440 is provided with a second throttle valve.

The vibration plate vibrates the actuator into the first chute 310 of the inlet slide rail 300, and simultaneously blows air to the sliding direction of the actuator through the first inclined air passages 330, so that the actuator is sequentially and stably slid into the arranged arc-shaped slide rail 500 and the outlet slide rail 400. A pair of inclined air passages II 430 are arranged on the outlet slide rail 400 near the head, the pair of inclined air passages II 430 blow air in the sliding direction of the actuator, the actuator is given a thrust force in a sufficient advancing direction by adjusting the size of the throttle valve II, the front end of the outlet slide rail is connected with the actuator star wheel, when the photoelectric sensor 700 arranged on the outlet slide rail 400 detects that the actuator is fully distributed to the detection groove 450, a rotating signal for triggering the actuator star wheel is given, and the actuator can be ensured to be efficiently and smoothly rotated into the actuator mounting station; at least more than 6 actuator stations are arranged between the detection groove 450 and the actuator star wheel, so that the condition that the actuator star wheel is leaked in the deceleration stop time is ensured not to happen.

For the purposes of this disclosure, the following points are also described:

(1) The drawings of the embodiments disclosed in the present application relate only to the structures related to the embodiments disclosed in the present application, and other structures can refer to common designs;

(2) The embodiments disclosed herein and features of the embodiments may be combined with each other to arrive at new embodiments without conflict;

the above is only a specific embodiment disclosed in the present application, but the protection scope of the present disclosure is not limited thereto, and the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (9)

1. An actuator automatic feed rail, comprising:

the inlet slide rail is fixedly arranged on the vibration material arranging mounting plate and is connected with a discharge hole of the vibration plate; the inlet sliding rail is provided with a first sliding groove matched with the actuator; the inlet sliding rail is provided with an air passage I extending along the length direction of the inlet sliding rail, the air passage I is provided with a plurality of inclined air passages I communicated with the sliding groove I, and the inclined air passages extend towards the sliding direction of the actuator; and

the head part of the outlet slide rail is fixedly connected with the inlet slide rail, and the tail part of the outlet slide rail extends to the positioning bottom plate; and a second sliding groove matched with the actuator is formed in the outlet sliding rail.

2. The automatic actuator feeding rail according to claim 1, wherein the outlet slide rail is provided with a second air passage extending along the length direction of the outlet slide rail, the second air passage is provided with a plurality of second inclined air passages communicated with the second sliding groove, and the second inclined air passages extend towards the sliding direction of the actuator.

3. The actuator automatic feed rail of claim 1, wherein an arc-shaped slide rail fixedly connected is arranged between the inlet slide rail and the outlet slide rail;

and a sliding groove III matched with the actuator is formed in the arc-shaped sliding rail.

4. The actuator automatic feed rail of claim 1, wherein the inlet rail is provided with a primary air hole I;

and the first main air hole is provided with an extension air passage I communicated with the first air passage.

5. The actuator autofeed rail of claim 1 or 4, wherein one of said air passages is provided with a pair of symmetrically disposed on said inlet rail.

6. The actuator automatic feed rail according to claim 1, wherein the outlet slide rail is provided with a second main air hole;

and the second main air hole is provided with a second extension air passage communicated with the second air passage.

7. The actuator automatic feed track of claim 6, wherein the second air passage is provided with a pair of symmetrically disposed on the outlet slide rail.

8. The actuator autofeed rail of claim 1, wherein the inlet rail is adjustably secured to the vibratory finishing mounting plate by a rail bracket.

9. The actuator automatic feed rail of claim 8, wherein the bottom of the slide rail bracket is adjustably and fixedly connected with the vibration material arranging mounting plate, and the top of the slide rail bracket is provided with a hinge groove;

the hinge groove is hinged with a hinge block through a connecting piece, and the hinge block is fixedly connected with the bottom of the inlet sliding rail in an adjustable mode.