CN215586833U - Release agent nozzle structure for aluminum alloy forming - Google Patents

Abstract

The utility model belongs to the field of spray nozzles, and provides a mold release nozzle structure for aluminum alloy forming, which comprises: the spraying main body is provided with a plurality of nozzles, a first gas channel, a second gas channel and a glue injection channel, wherein the first gas channel, the second gas channel and the glue injection channel are communicated with each nozzle; the gasket is arranged on the cavity and used for isolating the communication between the glue injection channel and the nozzle; and the locking cover abuts against the gasket and is detachably connected with the cavity, and an airflow groove is formed in the locking cover and communicated with the second gas channel. Compared with the prior art, the spraying device has the advantages that the spraying main body is regularly provided with the plurality of nozzles, and the spraying main body can spray a mold quickly and effectively.

Description

Release agent nozzle structure for aluminum alloy forming

Technical Field

The utility model belongs to the field of spray nozzles, and particularly relates to a mold release nozzle structure for aluminum alloy forming.

Background

The release agent is a demolding liquid for separating a mold and a die casting, an old release agent spraying process generally adopts a spray head consisting of copper pipes to singly spray or manually spray, the modes have long operation time, the mold cannot be quickly and completely sprayed, and further the die casting is damaged, and the release agent cannot be sprayed out or cannot be stopped easily in the spraying process of die casting production by the existing spray head consisting of copper pipes.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of the prior art and provides a mold release nozzle structure for aluminum alloy forming, which is convenient and quick, can spray in a large scale and has strong practicability.

The technical scheme adopted by the utility model for solving the technical problems is as follows: a release nozzle configuration for aluminum alloy forming is presented, comprising:

the spraying main body is provided with a nozzle, a first gas channel, a second gas channel and a glue injection channel, wherein the first gas channel, the second gas channel and the glue injection channel are communicated with the nozzle;

the gasket is arranged on the cavity and used for isolating the communication between the glue injection channel and the nozzle;

and the locking cover abuts against the gasket and is detachably connected with the cavity, and an airflow groove is formed in the locking cover and communicated with the second gas channel.

In the above-described mold release nozzle configuration for aluminum alloy forming, the gas flow groove includes: the second gas channel is connected with the cavity, and the airflow holes are communicated with the flow guide grooves.

In the mold release nozzle structure for aluminum alloy forming, the locking cover is in threaded connection with the cavity.

In the above mold release nozzle structure for aluminum alloy forming, an annular object holding groove is formed in the cavity, and the gasket is detachably arranged on the annular object holding groove.

In the above mold release nozzle structure for aluminum alloy forming, the gasket is a circular flexible gasket.

In the above mold release nozzle structure for aluminum alloy forming, the nozzle has a first spray cavity and a second spray cavity, the first spray cavity is communicated with the glue injection channel, and the second spray cavity is communicated with the first gas channel.

In the above-mentioned mold release nozzle structure for aluminum alloy forming, the second spray chamber annularly surrounds the first spray chamber.

In the above mold release nozzle structure for forming aluminum alloy, the spray main body is further provided with a purging air inlet channel.

Compared with the prior art, the utility model has the following beneficial effects:

1. the regularity is provided with the nozzle in the main part that sprays, can spray the mould fast effectually through spraying the main part, guarantees that the mold release can spray to the place of mould, and then makes quick and complete completion drawing of patterns of plunger spare.

2. The inside circular flexible gasket of detachable that is provided with of nozzle, when spraying, the mold release flows into cavity department through the injecting glue passageway, because the pressure of mold release is greater than the power that the gasket bore and then pushes down the gasket, pushes down in-process mold release and spouts from first spraying chamber department, when stopping spraying, the gas of spouting in the second gas passage, gas pressure is greater than the pressure that the top gasket pushed down, returns the gasket and resets, and the gasket supports with first spraying chamber department and leans on.

3. The mixed gas flows into the second spray cavity from the second gas channel, and the mold can be uniformly sprayed by the release agent flowing out of the first spray cavity.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a structural cross-sectional view of the present invention;

fig. 3 is a schematic structural view of the locking cap.

In the figure, 1, a spray main body; 2. a nozzle; 3. a first gas passage; 4. a second gas passage; 5. a glue injection channel; 6. a cavity; 7. a gasket; 8. a locking cover; 9. an air flow groove; 10. an arc groove; 11. an airflow aperture; 12. a diversion trench; 13. an annular storage groove; 14. a first spray chamber; 15. a second spray chamber; 16. and purging the air inlet channel.

Detailed Description

The following are specific embodiments of the present invention and are further described with reference to the drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 3, the present mold release nozzle 2 configuration for aluminum alloy forming includes: the spraying device comprises a spraying main body 1, a first gas channel 3, a second gas channel 4 and a glue injection channel 5, wherein the spraying main body is provided with a nozzle 2, and the first gas channel 3, the second gas channel 4 and the glue injection channel 5 are communicated with the nozzle 2; the gasket 7 is arranged on the cavity 6, and the gasket 7 is used for isolating the communication between the glue injection channel 5 and the nozzle 2; the locking cover 8 abuts against the gasket 7 and is detachably connected with the cavity 6, an airflow groove 9 is formed in the locking cover 8, and the airflow groove 9 is communicated with the second gas channel 4.

The spray main body 1 is regularly provided with nozzles 2, a gasket 7 is placed in a cavity 6 and is locked by a locking cover 8 to the gasket 7, so that the gasket 7 is tightly abutted against the nozzles 2, the glue injection channel 5 cannot be communicated with the nozzles 2, when the equipment is started, a parting agent flows into the cavity 6 from the glue injection channel 5, the center of the gasket 7 is pressed down due to the fact that the pressure of the parting agent is larger than the force borne by the gasket 7, the glue injection channel 5 is communicated with the nozzles 2 again in the pressing-down process of the center of the gasket 7, the parting agent flows out from the nozzles 2, mixed gas is arranged in the first gas channel 3, meanwhile, the mixed gas in the first gas channel 3 is sprayed out to uniformly spray the parting agent to a mold, high-pressure gas is arranged in the second gas channel 4, after the mold is sprayed, the high-pressure gas in the second gas channel 4 is flushed to the gasket 7 from the airflow groove 9, and the pressure of the high-pressure gas is larger than that of the gasket 7, the gasket 7 is forced to be pressed against the nozzle 2 upwards, the glue injection channel 5 is not communicated with the nozzle 2, and then automatic spraying is realized.

Preferably, the air flow groove 9 includes: the arc groove 10 and the airflow holes 11 evenly arranged on the side wall of the arc groove 10, the diversion trench 12 is arranged at the cavity 6 connected with the second gas channel 4, and the airflow holes 11 are communicated with the diversion trench 12.

High-pressure gas in the second gas channel 4 flows into the arc groove 10 through the airflow holes 11 uniformly, so that the gasket 7 is quickly and effectively flushed upwards by the high-pressure gas, and the arc groove 10 is convenient for the gasket 7 to be sunken downwards under the pressure of a release agent so as to provide a communicating space for the glue injection channel 5 and the nozzle 2.

Preferably, the locking cap 8 is screwed to the cavity 6.

Locking lid 8 and 6 threaded connection of cavity are convenient follow-up 7 and the inside maintenance of nozzle 2, and the benefit that sets up like this need not whole purchase again when nozzle 2 blocks up or damages, only need unpack apart and repair the internals, and then reduce cost of maintenance.

Further preferably, an annular object placing groove 13 is formed in the cavity 6, and the gasket 7 is detachably arranged on the annular object placing groove 13.

Even if the annular storage groove 13 is convenient for fixing the gasket 7, the release agent can not flow into the cavity 6 from the edge of the gasket 7.

Further preferably, the gasket 7 is a circular flexible gasket.

The gasket 7 is a plastic gasket, and the pressure of the flowing liquid of the mold release agent flushed into the cavity 6 can force the gasket 7 to be sunken downwards so as to provide a communicating space for the glue injection channel 5 and the nozzle 2.

Preferably, the nozzle 2 has a first spraying cavity 14 and a second spraying cavity 15, the first spraying cavity 14 is communicated with the glue injection channel 5, and the second spraying cavity 15 is communicated with the first gas channel 3.

The first nozzle 2 is used for spraying the parting agent, and the second nozzle 2 is used for spraying the mixed gas to atomize the parting agent.

It is further preferred that the second nozzle chamber 15 annularly surrounds the first nozzle chamber 14.

The mixed gas flows into the second spraying cavity 15 from the second gas channel 4, so that the release agent flowing out of the first spraying cavity 14 can be sprayed to the mold more quickly and uniformly by the high-pressure mixed gas.

Preferably, the shower main body 1 is further provided with a purge inlet passage 16.

The mold can be air swept by blowing air ejected from the air intake passage 16.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

Moreover, descriptions of the present invention as relating to "first," "second," "a," etc. are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit ly indicating a number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the technical solutions in the embodiments of the present invention may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination of technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Claims (8)

1. A release nozzle configuration for aluminum alloy forming, comprising:

the spraying main body is provided with a nozzle, a first gas channel, a second gas channel and a glue injection channel, wherein the first gas channel, the second gas channel and the glue injection channel are communicated with the nozzle;

the gasket is arranged on the cavity and used for isolating the communication between the glue injection channel and the nozzle;

and the locking cover abuts against the gasket and is detachably connected with the cavity, and an airflow groove is formed in the locking cover and communicated with the second gas channel.

2. A release nozzle configuration for aluminum alloy forming according to claim 1, wherein the gas flow channel comprises: the second gas channel is connected with the cavity, and the airflow holes are communicated with the flow guide grooves.

3. The release nozzle configuration for aluminum alloy forming of claim 2, wherein the locking cap is threaded with the cavity.

4. The mold release nozzle structure for aluminum alloy forming of claim 1, wherein the cavity is provided with an annular storage groove, and the gasket is detachably mounted on the annular storage groove.

5. The release nozzle configuration for aluminum alloy forming of claim 4, wherein the gasket is a circular flexible gasket.

6. The mold release nozzle structure for aluminum alloy forming of claim 1, wherein the nozzle has a first spray cavity and a second spray cavity, the first spray cavity is communicated with the glue injection channel, and the second spray cavity is communicated with the first gas channel.

7. A release nozzle configuration for aluminum alloy forming according to claim 6, wherein the second spray chamber annularly surrounds the first spray chamber.

8. The mold release nozzle structure for aluminum alloy forming according to claim 1, wherein the spray main body is further provided with a purge gas inlet channel.

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