CN215242806U - Mould fortune water structure - Google Patents

Abstract

The utility model discloses a mould fortune water structure, including the main shaft, the length extending direction cover along the main shaft on the main shaft is equipped with overcoat dish and water diversion disc, the interval is provided with main inlet channel and main water outlet channel in the main shaft, main inlet channel all extends along the length direction of main shaft with main water outlet channel, be provided with inlet opening and apopore on the overcoat dish, the inlet opening communicates in main inlet channel, the apopore communicates in main water outlet channel, it has a plurality of son return water channels and son water outlet channel to encircle main shaft circumference array on the water diversion disc, all son return water channels all communicate in main water outlet channel, all son water outlet channels all communicate in main inlet channel, the utility model discloses utilize main shaft itself as fortune water structure, reduce setting up of pipeline for the complete machine is arrange in order more easily, simplifies the complete machine structure, and the practicality is strong.

Description

Mould fortune water structure

Technical Field

The utility model relates to a core especially relates to a mould fortune water structure.

Background

The bottle blowing machine is internally provided with a mold for product molding, the mold is usually provided with a water cooling structure for cooling a molded product, the water cooling structure needs to continuously add water and discharge water, the traditional bottle blowing machine is provided with a corresponding water separator for each mold, water is fed into the water separator through a pipeline and then is input into the corresponding mold, cooling water in the mold flows back into the water separator to flow away, so that more pipelines are erected, a plurality of pipelines are staggered and messy, and the whole water conveying structure increases the overall structure of the bottle blowing machine.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a mould fortune water structure to solve one or more technical problem that exist among the prior art, provide a profitable selection or create the condition at least.

The utility model provides a solution of its technical problem is:

the utility model provides a mould fortune water structure, includes the main shaft, follow on the main shaft the length extending direction cover of main shaft is equipped with overcoat dish and diversion disc, the interval is provided with main inlet channel and main water outlet channel in the main shaft, main inlet channel with main water outlet channel all follows the length direction of main shaft extends, be provided with inlet opening and apopore on the overcoat dish, the inlet opening communicate in main inlet channel, the apopore communicate in main water outlet channel, wind on the diversion disc main shaft circumference array has a plurality of sub-water return channels and sub-water outlet channel, all sub-water return channels all communicate in main water outlet channel, all sub-water outlet channel all communicate in main inlet channel.

The technical scheme at least has the following beneficial effects: the outer sleeve disc and the water distribution disc are sleeved on the main shaft and synchronously rotate along with the main shaft, when water is needed to be supplied to an external die, cooling water is input into the water inlet hole, the cooling water flows into the sub water outlet channels in the water distribution disc through the main water inlet channel, each sub water outlet channel can be connected with a pipeline and communicated into one die, the cooling water is supplied into the die, the cooling water flowing out of the die can also flow into the sub water return channels through the pipelines, and the cooling water is discharged after converging into the main water outlet channels from the sub water return channels.

As a further improvement of the above technical solution, the inner side wall of the water diversion disc is provided with a first connection groove around the center line of the water diversion disc, the side wall of the main shaft is provided with a first connection hole, one end of the first connection hole is communicated with the first connection groove, the other end of the first connection hole is connected to the main water inlet channel, all the sub water outlet channels extend along the radial direction of the water diversion disc, one end of each sub water outlet channel extends to the outer side wall of the water diversion disc, and the other end of each sub water outlet channel is connected to the first connection groove. The water diversion disc is sleeved on the main shaft, the outer side wall of the main shaft shields and seals the first connecting groove and encloses an annular water inlet channel, and cooling water introduced into the main water inlet channel flows into the water inlet channel through the first connecting hole and then is distributed to the sub water outlet channels.

As a further improvement of the technical scheme, the outer side wall of the water distribution disc of the sub water outlet channel is provided with a mold water inlet interface. The sub water outlet channel is provided with a mould water inlet interface at one end opening far away from the main shaft, and an external pipeline can be quickly connected to the mould water inlet interface, so that the use is convenient.

As a further improvement of the above technical solution, the inner side wall of the water diversion disc surrounds the center line of the water diversion disc and is provided with a second connecting groove, the side wall of the main shaft is provided with a second connecting hole, one end of the second connecting hole is communicated with the second connecting groove, the other end of the second connecting hole is connected with the main water outlet channel, all the sub-water return channels all follow the radial extension of the water diversion disc, one end of the sub-water return channel extends to the outer side wall of the water diversion disc, and the other end of the sub-water return channel is connected with the second connecting groove. And after the water distribution disc is sleeved on the main shaft, the outer side wall of the main shaft shields and seals the second connecting groove and encloses an annular water outlet channel, cooling water flowing back from each sub water outlet channel converges into the water outlet channel, and flows into the main water outlet channel from the second connecting hole.

As a further improvement of the technical scheme, the sub-water return channel is positioned on the outer side wall of the water distribution disc and is provided with a mold water outlet interface. A mold water outlet port is formed in one end opening, far away from the main shaft, of the sub-water return channel, and an external pipeline can be quickly connected to the mold water outlet port, so that the use is convenient.

As a further improvement of the above technical solution, the water inlet is located on the end surface of the outer sleeve disc far away from the water distribution disc, a third connecting hole is provided in the outer sleeve disc, a fourth connecting hole is provided on the outer side wall of the main shaft, one end of the fourth connecting hole is connected to the main water inlet channel, the other end of the fourth connecting hole is communicated with one end of the third connecting hole, and the other end of the third connecting hole is connected to the water inlet. The pipeline of peripheral hardware can be connected to the inlet opening that is located outer sleeve dish terminal surface, and the pipeline of peripheral hardware is followed when the main shaft rotates and is rotated, reduces its swing range, and the external cooling water that lets in can follow the inlet opening and get into main inlet channel behind third connecting hole, the fourth connecting hole in proper order.

As a further improvement of the above technical scheme, the water outlet hole is located on an end surface of the outer sleeve disc far away from the water distribution disc, a fifth connecting hole is arranged in the outer sleeve disc, a sixth connecting hole is arranged on an outer side wall of the main shaft, one end of the sixth connecting hole is connected to the main water outlet channel, the other end of the sixth connecting hole is communicated with one end of the fifth connecting hole, and the other end of the fifth connecting hole is connected to the water outlet hole. The external pipeline can be connected to the water outlet hole in the end face of the outer sleeve disc, the external pipeline rotates along with the main shaft when the main shaft rotates, the swing amplitude of the main shaft is reduced, and cooling water flowing out of the main water outlet channel can sequentially flow through the sixth connecting hole and the fifth connecting hole and then flow out of the water outlet hole.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below. It is clear that the described figures represent only some embodiments of the invention, not all embodiments, and that a person skilled in the art can also derive other designs and figures from these figures without inventive effort.

Fig. 1 is an overall structure front view of the present invention;

FIG. 2 is a schematic view of the cross-sectional structure A-A of FIG. 1;

FIG. 3 is a schematic view of the cross-sectional structure B-B of FIG. 1;

fig. 4 is a schematic view of the cross-sectional structure C-C of fig. 1.

In the drawings: 100-main shaft, 110-main water inlet channel, 120-main water outlet channel, 130-first connecting hole, 140-second connecting hole, 150-fourth connecting hole, 160-sixth connecting hole, 200-outer sleeve disc, 210-water inlet hole, 220-water outlet hole, 230-third connecting hole, 240-fifth connecting hole, 300-water diversion disc, 310-sub water return channel, 311-mold water outlet interface, 320-sub water outlet channel, 321-mold water inlet interface, 330-first connecting groove and 340-second connecting groove.

Detailed Description

The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the connection relations mentioned herein do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection accessories according to the specific implementation situation. All technical characteristics in the invention can be interactively combined on the premise of not conflicting with each other.

Referring to fig. 1 and 2, a mold water conveying structure includes a main shaft 100, an outer sleeve 200 and a water diversion disc 300 are sleeved on the main shaft 100 along a length extending direction of the main shaft 100, main water inlet channels 110 and main water outlet channels 120 are arranged in the main shaft 100 at intervals, the main water inlet channels 110 and the main water outlet channels 120 extend along the length direction of the main shaft 100, water inlet holes 210 and water outlet holes 220 are formed in the outer sleeve 200, the water inlet holes 210 are communicated with the main water inlet channels 110, the water outlet holes 220 are communicated with the main water outlet channels 120, a plurality of sub water return channels 310 and sub water outlet channels 320 are arranged on the water diversion disc 300 around the main shaft 100 in a circumferential array, all the sub water return channels 310 are communicated with the main water outlet channels 120, and all the sub water outlet channels 320 are communicated with the main water inlet channels 110.

From the above, the outer sleeve 200 and the water diversion disc 300 are sleeved on the main shaft 100 and rotate synchronously with the main shaft 100, when water is required to be supplied to an external mold, cooling water is input to the water inlet 210, the cooling water flows into the sub water outlet channels 320 in the water diversion disc 300 through the main water inlet channel 110, each sub water outlet channel 320 can be connected with a pipeline and communicated with one mold, the cooling water is supplied to the interior of the mold, the cooling water flowing out of the mold can also flow into the sub water return channels 310 through the pipeline, and the cooling water flows into the main water outlet channel 120 from the sub water return channels 310 and is discharged.

As shown in fig. 3, as a further embodiment in which the sub water outlet channels 320 in the water diversion disc 300 are communicated with the main water inlet channel 110 on the main shaft 100, the inner side wall of the water diversion disc 300 is provided with a first connection groove 330 around the center line of the water diversion disc 300, the side wall of the main shaft 100 is provided with a first connection hole 130, one end of the first connection hole 130 is communicated with the first connection groove 330, the other end of the first connection hole 130 is connected to the main water inlet channel 110, all the sub water outlet channels 320 extend along the radial direction of the water diversion disc 300, one end of the sub water outlet channel 320 extends to the outer side wall of the water diversion disc 300, and the other end of the sub water outlet channel 320 is connected to the first connection groove 330. After the water diversion disc 300 is sleeved on the main shaft 100, the outer side wall of the main shaft 100 shields and seals the first connecting groove 330 and encloses an annular water inlet channel, and the cooling water introduced into the main water inlet channel 110 flows into the water inlet channel through the first connecting hole 130 and then is diverted to each sub water outlet channel 320.

As a further embodiment of the sub water outlet channel 320, a mold water inlet interface 321 is disposed on the outer side wall of the water diversion plate 300 of the sub water outlet channel 320. The water inlet port 321 of the mold is disposed at a port of the sub-water outlet channel 320 far away from the main shaft 100, and the external pipeline can be quickly connected to the water inlet port 321 of the mold, so that the use is convenient.

As shown in fig. 4, as a further embodiment in which the sub-water return passage 310 in the water diversion disc 300 is communicated with the main water outlet passage 120 in the main shaft 100, a second connection groove 340 is disposed on the inner side wall of the water diversion disc 300 around the center line of the water diversion disc 300, a second connection hole 140 is disposed on the side wall of the main shaft 100, one end of the second connection hole 140 is communicated with the second connection groove 340, the other end of the second connection hole 140 is connected to the main water outlet passage 120, all the sub-water return passages 310 extend along the radial direction of the water diversion disc 300, one end of each sub-water return passage 310 extends to the outer side wall of the water diversion disc 300, and the other end of each sub-water return passage 310 is connected to the second connection groove 340. After the water diversion disc 300 is sleeved on the main shaft 100, the outer side wall of the main shaft 100 shields and seals the second connection groove 340 and encloses an annular water outlet channel, and the cooling water flowing back from each sub water outlet channel 320 converges to the water outlet channel and flows into the main water outlet channel 120 from the second connection hole 140.

As a further embodiment of the sub-water return passage 310, a mold water outlet interface 311 is disposed on the outer side wall of the water diversion disc 300 of the sub-water return passage 310. The sub-water return passage 310 is provided with a mold water outlet 311 at an end opening far away from the main shaft 100, and an external pipeline can be quickly connected to the mold water outlet 311, so that the use is convenient.

As a further embodiment in which the water inlet 210 is communicated with the main water inlet channel 110, the water inlet 210 is located on an end surface of the outer sleeve 200 away from the water diversion disc 300, a third connection hole 230 is provided in the outer sleeve 200, a fourth connection hole 150 is provided on an outer side wall of the main shaft 100, one end of the fourth connection hole 150 is connected to the main water inlet channel 110, the other end of the fourth connection hole 150 is communicated with one end of the third connection hole 230, and the other end of the third connection hole 230 is connected to the water inlet 210. The external pipeline may be connected to the water inlet hole 210 located at the end surface of the outer sleeve 200, the external pipeline rotates along with the rotation of the main shaft 100 to reduce the swing amplitude thereof, and the introduced external cooling water may sequentially pass through the third connection hole 230 and the fourth connection hole 150 from the water inlet hole 210 and then enter the main water inlet channel 110.

As a further embodiment of the mutual communication between the water outlet hole 220 and the main water outlet channel 120, the water outlet hole 220 is located on an end surface of the outer sleeve 200 away from the water distribution disc 300, a fifth connection hole 240 is disposed in the outer sleeve 200, a sixth connection hole 160 is disposed on an outer side wall of the main shaft 100, one end of the sixth connection hole 160 is connected to the main water outlet channel 120, the other end of the sixth connection hole 160 is communicated with one end of the fifth connection hole 240, and the other end of the fifth connection hole 240 is connected to the water outlet hole 220. The external pipes may be connected to the water outlet holes 220 located on the end surface of the outer sleeve 200, the external pipes rotate along with the main shaft 100 when the main shaft rotates, so as to reduce the swing amplitude, and the cooling water flowing out of the main water outlet passage 120 may sequentially pass through the sixth connection hole 160 and the fifth connection hole 240 and then flow out of the water outlet holes 220.

While the preferred embodiments of the present invention have been described in detail, it will be understood by those skilled in the art that the invention is not limited to the details of the embodiments shown, but is capable of various modifications and substitutions without departing from the spirit of the invention.

Claims (7)

1. The utility model provides a mould fortune water structure which characterized in that: comprises a main shaft (100), an outer sleeve disc (200) and a water diversion disc (300) are sleeved on the main shaft (100) along the length extension direction of the main shaft (100), a main water inlet channel (110) and a main water outlet channel (120) are arranged in the main shaft (100) at intervals, the main water inlet channel (110) and the main water outlet channel (120) both extend along the length direction of the main shaft (100), the outer sleeve disc (200) is provided with a water inlet hole (210) and a water outlet hole (220), the water inlet hole (210) is communicated with the main water inlet channel (110), the water outlet hole (220) is communicated with the main water outlet channel (120), the water distribution disc (300) is provided with a plurality of sub water return channels (310) and sub water outlet channels (320) in a circumferential array around the main shaft (100), all the sub water return channels (310) are communicated with the main water outlet channel (120), and all the sub water outlet channels (320) are communicated with the main water inlet channel (110).

2. The mold water transport structure according to claim 1, wherein: the inside wall of distributive disc (300) encircles the central line of distributive disc (300) is provided with first connecting groove (330), the lateral wall of main shaft (100) is provided with first connecting hole (130), the one end of first connecting hole (130) communicate in first connecting groove (330), the other end of first connecting hole (130) connect in main inlet channel (110), all sub-water outlet channel (320) are all followed the radial extension of distributive disc (300), the one end of sub-water outlet channel (320) extends to the lateral wall of distributive disc (300), the other end of sub-water outlet channel (320) connect in first connecting groove (330).

3. The mold water transport structure according to claim 2, wherein: and the sub water outlet channel (320) is positioned on the outer side wall of the water distribution disc (300) and is provided with a mold water inlet interface (321).

4. The mold water transport structure according to claim 1, wherein: the inside wall of distributive disc (300) encircles the central line of distributive disc (300) is provided with second spread groove (340), the lateral wall of main shaft (100) is provided with second connecting hole (140), the one end of second connecting hole (140) communicate in second spread groove (340), the other end of second connecting hole (140) connect in main water outlet channel (120), all sub-return water course (310) are all followed the radial extension of distributive disc (300), the one end of sub-return water course (310) extends to the lateral wall of distributive disc (300), the other end of sub-return water course (310) connect in second spread groove (340).

5. The mold water transport structure according to claim 4, wherein: and the sub-water return channel (310) is positioned on the outer side wall of the water distribution disc (300) and is provided with a mold water outlet interface (311).

6. The mold water transport structure according to claim 1, wherein: the water inlet hole (210) is located the outer sleeve disc (200) is kept away from on the terminal surface of water distribution disc (300), be provided with third connecting hole (230) in the outer sleeve disc (200), the lateral wall of main shaft (100) is provided with fourth connecting hole (150), the one end of fourth connecting hole (150) connect in main inlet channel (110), the other end of fourth connecting hole (150) communicate in the one end of third connecting hole (230), the other end of third connecting hole (230) connect in water inlet hole (210).

7. The mold water transport structure according to claim 1, wherein: apopore (220) are located outer race dish (200) are kept away from on the terminal surface of water distribution dish (300), be provided with fifth connecting hole (240) in outer race dish (200), the lateral wall of main shaft (100) is provided with sixth connecting hole (160), the one end of sixth connecting hole (160) connect in main outlet channel (120), the other end of sixth connecting hole (160) communicate in the one end of fifth connecting hole (240), the other end of fifth connecting hole (240) connect in apopore (220).

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