CN219222948U - Circulating cooling water system for vacuum ion coating machine - Google Patents

Abstract

The utility model discloses a circulating cooling water system for a vacuum ion plating machine, relates to the field of vacuum ion plating machines, and solves the problems that the existing cooling water of the vacuum ion plating machine is discharged after being used and then is added again, so that certain waste is caused, and a large amount of time is consumed during replacement, so that the working efficiency is reduced. The technical characteristics include a supporting base; the bearing structure is arranged on the upper surface of the supporting base and is used for bearing cooling water; the first connecting structure is arranged on the bearing structure and is used for being connected with the vacuum ion plating machine. The consumption of resources is reduced, the working efficiency is increased, the quality of cooling water is guaranteed, the structure is relatively simple, and the use is convenient.

Description

Circulating cooling water system for vacuum ion coating machine

Technical Field

The utility model relates to the technical field of vacuum ion coating machines, in particular to a circulating cooling water system for a vacuum ion coating machine.

Background

Vacuum coating is a technique of physically producing a thin film material in which atoms of the material are separated from a heating source in a vacuum chamber and are applied to the surface of an object to be coated. The technology is firstly used for producing optical lenses, such as navigation telescope lenses and the like; and then the film is extended to other functional films, such as aluminizing of record, decorative coating, material surface modification and the like, for example, gold-like coating of watch shell, mechanical cutter coating, and change of processing red hardness. There are three types of vacuum coating, namely, evaporation coating, sputter coating and ion plating.

The cooling water of the existing vacuum ion plating machine is discharged after being used and then is added again, so that certain waste is caused, and a great amount of time is consumed during replacement, so that the working efficiency is reduced, and in order to solve the problem, it is very necessary to design a circulating cooling water system for the vacuum ion plating machine.

Disclosure of Invention

The utility model aims to solve the technical problems that the cooling water of the prior vacuum ion plating machine is discharged after being used and then added again, so that certain waste is caused, a great amount of time is consumed during replacement, and the working efficiency is reduced.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

a recirculating cooling water system for a vacuum ion plating machine, comprising:

a support base;

the bearing structure is arranged on the upper surface of the supporting base and is used for bearing cooling water;

the first connecting structure is arranged on the bearing structure and is used for connecting a vacuum ion plating machine;

the cooling structure is arranged on the upper surface of the supporting base and is used for cooling;

a first transfer structure mounted between the cooling structure and the housing structure, the first transfer structure for delivering water from within the housing structure into the cooling structure;

the temperature sensing structure is arranged in the cooling structure and is used for sensing temperature;

a reflow structure mounted on the cooling structure, the reflow structure for reflow;

and the discharging structure is arranged on the cooling structure and is used for being connected with the vacuum ion coating machine.

Preferably, the housing structure includes: the bearing water tank, the water inlet pipe, the first electric control valve, the water outlet pipe and the second electric control valve;

the bearing water tank is arranged on the upper surface of the supporting base, the water inlet pipe is arranged on the bearing water tank, the first electric control valve is arranged on the water inlet pipe, the water outlet pipe is arranged on the bearing water tank, and the second electric control valve is arranged on the water outlet pipe.

Preferably, the first connection structure includes: entering a connecting pipe and a third electric control valve;

the inlet connecting pipe is arranged on the bearing water tank, and the third electric control valve is arranged on the inlet connecting pipe.

Preferably, the cooling structure includes: the device comprises a bearing box body, a spiral pipe, a pair of first fixing frames and a pair of coolers;

the bearing box body is arranged on the upper surface of the supporting base, the spiral tube is arranged in the bearing box body, a pair of rectangular openings are formed in the bearing box body, each first fixing frame is arranged at the corresponding rectangular opening, and each cooling machine is arranged on the corresponding first fixing frame.

Preferably, the first conveying structure includes: the conveying pump comprises a second fixing frame, a conveying pump body and a conveying pipeline;

the second fixing frame is arranged on the bearing water tank, the conveying pump body is arranged on the second fixing frame, the conveying pump body is connected with the bearing water tank, the conveying pipeline is arranged on the conveying pump body, and the other end of the conveying pipeline is connected with the spiral pipe.

Preferably, the temperature sensing structure includes: a temperature sensor and a first transfer tube;

the first conveying pipe is arranged on the spiral pipe, and the temperature sensor is arranged on the first conveying pipe.

Preferably, the reflow structure includes: a return pump and a return pipe;

the reflux pump is arranged on the first conveying pipe, the reflux pipe is arranged on the reflux pump, and the reflux pipe is connected with the upper end of the spiral pipe.

Preferably, the discharging structure includes: a discharge connection pipe and a discharge connection valve;

the discharge connection pipe is installed on the first transfer pipe, and the discharge connection valve is installed on the discharge connection pipe.

Preferably, the support base is provided with a controller, and the support base is provided with a mains supply interface.

The utility model has the following beneficial effects:

this a recirculated cooling water system for vacuum ion coating machine can be better circulate cooling water, and is very convenient, has reduced unnecessary trouble, has reduced the consumption of resource, has increased work efficiency, has ensured the quality of cooling water, and the structure is simple relatively, convenient to use.

Drawings

The utility model is described in further detail below with reference to the drawings and the detailed description.

FIG. 1 is a schematic diagram of a circulating cooling water system for a vacuum ion plating machine according to the present utility model;

FIG. 2 is a schematic diagram of a circulating cooling water system for a vacuum ion plating machine according to the present utility model;

FIG. 3 is a front view of a recirculating cooling water system for a vacuum ion plating machine in accordance with the present utility model;

fig. 4 is a top view of a circulating cooling water system for a vacuum ion plating machine according to the present utility model.

Reference numerals in the drawings denote:

the support base 10, the housing structure 20, the first connection structure 30, the cooling structure 40, the first transfer structure 50, the temperature sensing structure 60, the reflow structure 70, the discharge structure 80, the controller 90, the utility interface 100;

the bearing water tank 21, the water inlet pipe 22, the first electric control valve 23, the water outlet pipe 24 and the second electric control valve 25;

a connecting pipe 31 and a third electric control valve 32 are entered;

the bearing box 41, the spiral tube 42, the first fixing frame 43 and the cooler 44;

a second fixing frame 51, a transmission pump body 52 and a transmission pipeline 53;

a temperature sensor 61 and a first transfer pipe 62;

a return pump 71 and a return pipe 72;

a discharge connection pipe 81 and a discharge connection valve 82.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of the utility model; it should be noted that, for convenience of description, in the present application, "left side" is "first end", "right side" is "second end", "upper side" is "first end", and "lower side" is "second end" in the current view, and the purpose of this description is to clearly express the technical solution, and should not be construed as unduly limiting the technical solution of the present application.

Referring to fig. 1 to 4, the supporting structure 20 on the upper surface of the supporting base 10 is used for supporting cooling water, the first connecting structure 30 on the supporting structure 20 is used for connecting with a vacuum ion plating machine, the cooling structure 40 on the upper surface of the supporting base 10 is used for cooling, the first conveying structure 50 is used for conveying water from the inside of the supporting structure 20 into the cooling structure 40, the temperature sensing structure 60 in the cooling structure 40 is used for sensing temperature, the reflow structure 70 on the cooling structure 40 is used for reflow, and the discharging structure 80 on the cooling structure 40 is used for connecting with the vacuum ion plating machine.

Preferably, the receiving structure 20 includes: the bearing water tank 21, the water inlet pipe 22, the first electric control valve 23, the water outlet pipe 24 and the second electric control valve 25; the bearing water tank 21 is installed on the upper surface of the supporting base 10, the water inlet pipe 22 is installed on the bearing water tank 21, the first electric control valve 23 is installed on the water inlet pipe 22, the water outlet pipe 24 is installed on the bearing water tank 21, and the second electric control valve 25 is installed on the water outlet pipe 24.

Cooling water is fed into the carrying water tank 21 through a water inlet pipe 22 on the carrying water tank 21, and can be discharged through a water outlet pipe 24 when the cooling water is required to be discharged, and is controlled through a first electric control valve 23 on the water inlet pipe 22 and a second electric control valve 25 on the water outlet pipe 24.

Preferably, the first connection structure 30 includes: entering a connecting pipe 31 and a third electric control valve 32; an inlet connection pipe 31 is mounted on the carrying tank 21, and a third electrically controlled valve 32 is mounted on the inlet connection pipe 31.

The used cooling water is returned to the bearing water tank 21 through the inlet connecting pipe 31, and the cooling water enters the third electric control valve 32 on the connecting pipe 31 for control.

Preferably, the cooling structure 40 includes: a carrying case 41, a spiral pipe 42, a pair of first holders 43, and a pair of coolers 44; the bearing box 41 is mounted on the upper surface of the supporting base 10, the spiral tube 42 is mounted in the bearing box 41, a pair of rectangular openings are formed in the bearing box 41, each first fixing frame 43 is mounted at the corresponding rectangular opening, and each cooler 44 is mounted on the corresponding first fixing frame 43.

The used cooling water is cooled by the spiral pipe 42 in the bearing box 41 in cooperation with the cooler 44 on the first fixing frame 43.

Preferably, the first transfer structure 50 includes: a second mount 51, a transfer pump body 52, and a transfer line 53; the second fixing frame 51 is installed on the bearing water tank 21, the conveying pump body 52 is installed on the second fixing frame 51, the conveying pump body 52 is connected with the bearing water tank 21, the conveying pipeline 53 is installed on the conveying pump body 52, and the other end of the conveying pipeline 53 is connected with the spiral pipe 42.

The cooled cooling water is sent out through the transfer pump body 52 and the transfer pipe 53 on the second fixing frame 51.

Preferably, the temperature sensing structure 60 includes: a temperature sensor 61 and a first transfer tube 62; the first transfer tube 62 is mounted on the spiral tube 42, and the temperature sensor 61 is mounted on the first transfer tube 62.

Whether the temperature of the cooling water reaches the standard or not is sensed by the temperature sensor 61, and the cooling water is conveyed out through the first conveying pipe 62 after reaching the standard.

Preferably, the reflow structure 70 includes: a return pump 71 and a return pipe 72; a return pump 71 is installed on the first transfer pipe 62, a return pipe 72 is installed on the return pump 71, and the return pipe 72 is connected to the upper end of the spiral pipe 42.

When the temperature of the cooling water does not reach the standard, the return pump 71 on the first delivery pipe 62 is started, and the cooling water is delivered back into the spiral pipe 42 through the return pipe 72 for re-cooling.

Preferably, the discharge structure 80 includes: a discharge connection pipe 81 and a discharge connection valve 82; the discharge connection pipe 81 is mounted on the first transfer pipe 62, and the discharge connection valve 82 is mounted on the discharge connection pipe 81.

The cooling water is discharged back into the vacuum ion plating machine through the discharge connection pipe 81.

Preferably, the controller 90 is disposed on the support base 10, and the mains interface 100 is disposed on the support base 10.

Is controlled by a controller 90 on the support base 10 and is connected to a power supply through a mains interface 100 on the support base 10.

It is apparent that the above examples are given by way of illustration only and are not limiting of the embodiments. Other variations or modifications of the above teachings will be apparent to those of ordinary skill in the art. It is not necessary here nor is it exhaustive of all embodiments. While still being apparent from variations or modifications that may be made by those skilled in the art are within the scope of the utility model.

Claims (9)

1. A recirculating cooling water system for a vacuum ion plating machine, comprising:

a support base (10);

the bearing structure (20), the said bearing structure (20) is installed on the upper surface of the supporting base (10), and the said bearing structure (20) is used for bearing the cooling water;

the first connecting structure (30), the first connecting structure (30) is installed on the bearing structure (20), and the first connecting structure (30) is used for connecting a vacuum ion plating machine;

a cooling structure (40), the cooling structure (40) being mounted to an upper surface of the support base (10), and the cooling structure (40) being for cooling;

a first transfer structure (50), the first transfer structure (50) being mounted between the cooling structure (40) and the receiving structure (20), and the first transfer structure (50) being for feeding water from within the receiving structure (20) into the cooling structure (40);

-a temperature sensing structure (60), the temperature sensing structure (60) being mounted within the cooling structure (40), and the temperature sensing structure (60) being adapted to sense temperature;

-a reflow structure (70), the reflow structure (70) being mounted on the cooling structure (40) and the reflow structure (70) being for reflow;

and the discharging structure (80) is arranged on the cooling structure (40), and the discharging structure (80) is used for being connected with the vacuum ion plating machine.

2. The circulating cooling water system for a vacuum ion plating machine according to claim 1, wherein the housing structure (20) includes: the bearing water tank (21), the water inlet pipe (22), the first electric control valve (23), the water outlet pipe (24) and the second electric control valve (25);

the bearing water tank (21) is arranged on the upper surface of the supporting base (10), the water inlet pipe (22) is arranged on the bearing water tank (21), the first electric control valve (23) is arranged on the water inlet pipe (22), the water outlet pipe (24) is arranged on the bearing water tank (21), and the second electric control valve (25) is arranged on the water outlet pipe (24).

3. The circulating cooling water system for a vacuum ion plating machine according to claim 2, wherein the first connection structure (30) comprises: entering a connecting pipe (31) and a third electric control valve (32);

the inlet connecting pipe (31) is arranged on the bearing water tank (21), and the third electric control valve (32) is arranged on the inlet connecting pipe (31).

4. A recirculating cooling water system for a vacuum ion plating machine according to claim 2, wherein the cooling structure (40) comprises: a carrying case (41), a spiral pipe (42), a pair of first fixing frames (43) and a pair of coolers (44);

the bearing box body (41) is arranged on the upper surface of the supporting base (10), the spiral tube (42) is arranged in the bearing box body (41), a pair of rectangular openings are formed in the bearing box body (41), each first fixing frame (43) is arranged at the corresponding rectangular opening, and each cooler (44) is arranged on the corresponding first fixing frame (43).

5. The circulating cooling water system for a vacuum ion plating machine according to claim 4, wherein the first transfer structure (50) comprises: a second fixing frame (51), a transmission pump body (52) and a transmission pipeline (53);

the second fixing frame (51) is arranged on the bearing water tank (21), the conveying pump body (52) is arranged on the second fixing frame (51), the conveying pump body (52) is connected with the bearing water tank (21), the conveying pipeline (53) is arranged on the conveying pump body (52), and the other end of the conveying pipeline (53) is connected with the spiral pipe (42).

6. The circulating cooling water system for a vacuum ion plating machine according to claim 4, wherein the temperature sensing structure (60) comprises: a temperature sensor (61) and a first transfer tube (62);

the first conveying pipe (62) is arranged on the spiral pipe (42), and the temperature sensor (61) is arranged on the first conveying pipe (62).

7. The circulating cooling water system for a vacuum ion plating machine according to claim 6, wherein the reflow structure (70) includes: a return pump (71) and a return pipe (72);

the reflux pump (71) is arranged on the first conveying pipe (62), the reflux pipe (72) is arranged on the reflux pump (71), and the reflux pipe (72) is connected with the upper end of the spiral pipe (42).

8. The circulating cooling water system for a vacuum ion plating machine according to claim 6, wherein the drain structure (80) comprises: a discharge connection pipe (81) and a discharge connection valve (82);

the discharge connection pipe (81) is mounted on the first transfer pipe (62), and the discharge connection valve (82) is mounted on the discharge connection pipe (81).

9. The circulating cooling water system for a vacuum ion plating machine according to claim 1, wherein a controller (90) is arranged on the supporting base (10), and a mains interface (100) is arranged on the supporting base (10).

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