A box type visualized water vapor unit

By designing a box-type visualized water-air unit in the welding equipment, using fixed partitions to separate the water and air paths, and achieving visualized control through a water pumping cylinder and an electrical control box, the problems of incomplete water-air separation and water overflow are solved, thus improving the intelligence and reliability of the equipment.

CN224381279UActive Publication Date: 2026-06-19TIANJIN MART TESTING EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TIANJIN MART TESTING EQUIP CO LTD
Filing Date
2025-06-06
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In existing technologies, during automated welding processes in manufacturing industries such as automobiles, ships, and aerospace, the water-air unit suffers from incomplete water-air separation, a non-compact structure, low level of intelligence, and the tendency for residual cooling water to leak out of the pipes when the welding clamp electrode cap is replaced.

Method used

A box-type visualized water-air unit was designed. The water and air paths are physically separated by a fixed partition inside the box. A water-pumping cylinder is used to prevent water from overflowing. Visual control is achieved through an electrical control box, which improves the level of intelligence.

Benefits of technology

It achieves physical separation of water and air, prevents water overflow, improves the level of intelligence and operational reliability, and facilitates the installation and maintenance of the equipment.

✦ Generated by Eureka AI based on patent content.

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    Figure CN224381279U_ABST
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Abstract

The utility model relates to a kind of box type visual water-gas unit, comprising: box, electric cabinet, gas path system, inlet waterway, backwater, box includes door, back cover, fixed baffle, fixed baffle is set between door and back cover and divides box into two cavities;Gas path system, inlet waterway, backwater are respectively with fixed baffle mechanical connection for realizing its installation fixed;Inlet waterway, backwater are all set in another cavity for realizing the physical separation with gas path system, the pipeline both ends of inlet waterway, backwater respectively from box stretch out;Electric cabinet is set on door and is respectively with gas path system, inlet waterway, backwater electric connection for realizing the electrical signal acquisition and control to above-mentioned equipment.The utility model embodiment design and layout are reasonable, dry and wet separation and installation move convenient and fast;Reduce water flow overflow, realize the visualization of water-gas unit, improve intelligent degree.
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Description

Technical Field

[0001] This utility model belongs to the field of automobile production equipment technology, and relates to a box-type visual water and air unit. Background Technology

[0002] In the automotive, shipbuilding, aerospace, and large machinery manufacturing industries, robotic welding guns utilize low voltage, high current, and short time to resistively melt the base metal at the electrode pressure point, forming a weld nugget. Cooling water is often required inside the welding gun to lower its temperature. In welding workstations, chillers are typically used to supply water to the robotic welding gun. However, current water-air units in production lines suffer from incomplete water-air separation, insufficient structural compactness, and low levels of intelligence. Residual cooling water can easily leak out of the pipes when replacing the electrode cap. Therefore, a new type of water-air unit is needed to address these issues. Utility Model Content

[0003] The purpose of this invention is to provide a box-type visual water-air unit that achieves physical separation of water and air, has a high degree of intelligence, and avoids the situation where residual cooling water in the pipes easily flows out when replacing the welding clamp electrode cap.

[0004] To achieve the above objectives, an embodiment of this utility model provides a box-type visual water-air unit, comprising: a box, an electrical control box, an air circuit system, a water inlet circuit, and a water return circuit. The box includes a door, a rear cover, and a fixed partition. The fixed partition is disposed between the door and the rear cover, dividing the box into two cavities. The air circuit system, the water inlet circuit, and the water return circuit are mechanically connected to the fixed partition for installation and fixation. The air circuit system includes an air source triplet disposed in one of the cavities, with both ends of the air circuit system's pipes extending from the box. The water inlet circuit and the water return circuit are both disposed in the other cavity for physical separation from the air circuit system, with both ends of the water inlet circuit and the water return circuit's pipes extending from the box. The electrical control box is disposed on the door and electrically connected to the air circuit system, the water inlet circuit, and the water return circuit for acquiring and controlling the electrical signals of the above-mentioned equipment.

[0005] Furthermore, the return water circuit includes: a return water ball valve, a second water fluid valve, a check valve, a return water tee, and a return water connector; the return water ball valve, the second water fluid valve, the check valve, the return water tee, and the return water connector are connected sequentially through pipelines to achieve water flow control of the return water circuit; the return water ball valve, the return water tee, and the return water connector are all located on the outside of the housing for easy connection to water sources and water-using equipment.

[0006] Furthermore, the return water circuit also includes: a return water tee and a pumping cylinder. The return water tee is positioned between the check valve and the return water tee connector. The pumping cylinder is connected to the return water tee via a pipeline to control the water flow in the return water circuit. The air circuit system also includes: an air circuit tee and a solenoid valve. The two ends of the solenoid valve are connected to the pumping cylinder and the air circuit tee via pipelines to control the operation of the pumping cylinder.

[0007] Furthermore, the gas circuit system also includes: a gas circuit ball valve and a gas circuit connector. The gas circuit ball valve, the gas source triplet, the gas circuit tee, and the gas circuit connector are connected in sequence through pipelines to realize the control of the gas circuit. The gas circuit ball valve and the gas circuit connector are both located on the outside of the housing for easy connection to the gas source and gas-using equipment.

[0008] Furthermore, the water inlet path includes: an inlet ball valve, a filter, a first water fluid valve, a water flow sensor, an inlet connector, and an inlet tee connector. The inlet ball valve, the filter, the first water fluid valve, the water flow sensor, the inlet tee connector, and the inlet connector are connected sequentially through pipelines to realize the monitoring and control of water flow in the water inlet path. The inlet ball valve, the inlet connector, and the inlet tee connector are all located on the outside of the housing for easy connection to water sources and water-using equipment.

[0009] Furthermore, the electrical control box is electrically connected to the air source triplet, the second water fluid valve, the first water fluid valve, and the water flow sensor to monitor or control the aforementioned equipment.

[0010] Furthermore, the electrical control box includes a control panel, which is a touch screen used to control the box-type visual water and gas unit and display information in real time.

[0011] Furthermore, it also includes a support frame, wherein the housing is disposed above the support frame and mechanically connected to the support frame.

[0012] Furthermore, it also includes: fixing clips, wherein the air circuit system, the water inlet circuit, and the water return circuit are all mechanically fixed to the fixing partition by a plurality of the fixing clips.

[0013] Preferably, the door and the rear cover are hinged to the box body to enable the door and the rear cover to be opened and closed.

[0014] This utility model relates to a box-type visualized water and air unit, with the following advantages: The embodiment of this utility model has a reasonable design and layout. Through the design of two cavity structures in the box, the water and air circuits are physically separated, achieving dry and wet separation and convenient and quick installation and movement; the use of a water pumping cylinder avoids water overflow during the disassembly and replacement of water-using equipment; and the use of an electrical control box with a control panel realizes the visualization of the water and air unit, improving the level of intelligence and operational reliability. Attached Figure Description

[0015] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings of the embodiments will be briefly introduced below. Obviously, the drawings described below only involve some embodiments of this utility model, and are not intended to limit this utility model.

[0016] Figure 1 This is a front view of the box-type visual water-air unit provided in Embodiment 1 of this utility model;

[0017] Figure 2 This is a front view of the internal structure of the box-type visual water-air unit provided in Embodiment 1 of this utility model;

[0018] Figure 3 A three-dimensional view of the front internal structure of the box-type visual water vapor unit provided in Embodiment 1 of this utility model;

[0019] Figure 4 This is a rear view of the box-type visual water-air unit provided in Embodiment 1 of this utility model;

[0020] Figure 5 This is a front view of the internal structure of the box-type visual water-air unit provided in Embodiment 1 of this utility model;

[0021] Figure 6 This is a three-dimensional view of the internal structure of the box-type visual water vapor unit provided in Embodiment 1 of this utility model;

[0022] Figure 7 This is a three-dimensional structural diagram of the box door provided in Embodiment 1 of this utility model;

[0023] Figure 8 This is a front view of the box-type visual water-air unit provided in Embodiment 2 of this utility model.

[0024] In the picture:

[0025] 1. Cabinet; 11. Cabinet Door; 12. Rear Cover; 13. Fixed Partition; 2. Electrical Control Box; 21. Control Panel; 3. Air System; 31. Air Ball Valve; 32. Air Source Triple Unit; 33. Air T-Connector; 34. Air Connector; 35. Solenoid Valve; 4. Water Inlet; 41. Water Inlet Ball Valve; 42. Filter; 43. First Water Fluid Valve; 44. Water Flow Sensor; 45. Water Inlet Connector; 46. Water Inlet T-Connector; 5. Water Return; 51. Water Return Ball Valve; 52. Second Water Fluid Valve; 53. Check Valve; 54. Water Return T-Connector; 55. Water Return Connector; 56. Water Return T-Connector; 57. Pumping Cylinder; 6. Bracket; 7. Fixing Buckle. Detailed Implementation

[0026] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some, not all, of the embodiments of this utility model. All other embodiments obtained by those skilled in the art based on the described embodiments of this utility model without creative effort are within the scope of protection of this utility model.

[0027] Unless otherwise defined, the technical or scientific terms used in this disclosure should have the ordinary meaning understood by one of ordinary skill in the art to which this disclosure pertains. It should be noted that terms such as "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," "front," and "rear," indicating orientation or positional relationships based on the orientation or positional relationships shown in the accompanying drawings, are used only for the convenience of describing the present invention and for simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of the present invention. Furthermore, terms such as "first," "second," "third," and "fourth," etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0028] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "joining" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0029] The following is a detailed description of a box-type visual water vapor unit provided by an embodiment of the present invention, with reference to the accompanying drawings.

[0030] Example 1

[0031] Figure 1 This shows a front view of the box-type visual water-air unit provided in Embodiment 1 of this utility model; Figure 2 This shows a front view of the internal structure of the box-type visual water-air unit provided in Embodiment 1 of this utility model; Figure 3 This shows a three-dimensional view of the front internal structure of the box-type visual water vapor unit provided in Embodiment 1 of this utility model; Figure 4 This shows a rear view of the box-type visual water-air unit provided in Embodiment 1 of the present invention; Figure 5 This shows a front view of the rear internal structure of the box-type visual water-air unit provided in Embodiment 1 of this utility model; Figure 6 This shows a three-dimensional view of the rear internal structure of the box-type visual water-air unit provided in Embodiment 1 of this utility model; Figure 7 A three-dimensional structural diagram of the cabinet door provided in Embodiment 1 of this utility model is shown. Figures 1 to 7As shown, the box-type visual water-air unit provided in Embodiment 1 of this utility model includes: a box 1, an electrical control box 2, an air circuit system 3, a water inlet 4, and a water return 5. The box 1 includes a door 11, a rear cover 12, and a fixed partition 13. The fixed partition 13 is disposed between the door 11 and the rear cover 12, dividing the box 1 into two cavities. In Embodiment 1 of this utility model, the box 1 is rectangular. The fixed partition 13 divides the box 1 into two rectangular cavity structures, realizing the physical separation of the water circuit and the air circuit, achieving dry and wet separation, and avoiding the impact of abnormal situations such as water leakage on the air circuit. The air circuit system 3, the water inlet 4, and the water return 5 are respectively connected to the fixed partition 11, the electrical control box 2, the air circuit system 3, the water inlet 4, and the water return 5. The partition plate 13 is mechanically connected to achieve its installation and fixation; the air circuit system 3 includes an air source triplet 32 ​​and is set in one of the cavities of the housing 1. The housing 1 is used to protect the key components in the air circuit system 3, avoiding the impact and damage of bumps and dust on the equipment, thereby improving the working reliability and service life of the air circuit system 3. The two ends of the pipeline of the air circuit system 3 extend from the corresponding openings on the housing 1. The air source triplet 32 ​​is composed of three key air source treatment components: an air filter (F), a pressure reducing valve (R), and an oil mist lubricator (L). It mainly provides purified, filtered, and pressure-reduced air to the air circuit to ensure that it obtains a stable rated pressure. Additionally, the gas system 3 also includes a gas ball valve 31 and a gas connector 34. The gas ball valve 31, gas source triplet 32, gas tee 33, and gas connector 34 are sequentially connected via pipelines to achieve gas transmission and control. Both the gas ball valve 31 and gas connector 34 are located on the outside of the housing 1 for easy connection to the gas source and gas-using equipment. This allows for connection to the gas source and gas-using equipment without opening the housing door 11, making the connection convenient and quick. In the housing-type visual water-gas unit provided in Embodiment 1 of this utility model, gas flows in from the gas ball valve 31. The gas ball valve 31 controls the flow rate and on / off state of the gas flow, which then passes through the gas source triplet 32... After purification and pressure control, an additional gas supply is added using the gas tee 33. Of course, one or more gas tees 33 can be set, and the specific number of gas tees 33 can be adjusted according to the user's specific needs. There is no limit to the number of gas tees 33 here. In the box-type visual water-gas unit provided in Embodiment 1 of this utility model, gas flows in from the gas ball valve 31 and flows out in two paths from the gas tee 33 and the gas connector 34. The gas connector 34 is connected to the corresponding gas-using equipment. Of course, one or more gas connectors 34 can also be set, and the specific number can be adjusted according to the user's specific needs.In the box-type visual water-gas unit provided in Embodiment 1 of this utility model, the water inlet 4 and the water return 5 are both located in another cavity in the box 1 to achieve physical separation from the gas system 3. The two ends of the water inlet 4 and the water return 5 extend from the corresponding openings on the box 1 to facilitate connection to a water source or water-using equipment without opening the box door 11. The electrical control box 2 is located on the box door 11 and is electrically connected to the corresponding components in the gas system 3, the water inlet 4, and the water return 5 to realize the acquisition and control of electrical signals of the above-mentioned equipment. The electrical control box 2 includes a control screen 21, which is preferably a touch screen for realizing the control of the box-type visual water-gas unit and real-time information display. In this way, the control screen 21 can realize human-computer interaction control and real-time monitoring of the equipment. The control screen 21 adopts the form of a touch screen for convenient and simple operation.

[0032] In the box-type visual water-air unit provided in Embodiment 1 of this utility model, more specifically, the return water circuit 5 includes: a return water ball valve 51, a second water fluid valve 52, a check valve 53, a return water tee connector 54, and a return water connector 55; wherein the return water ball valve 51, the second water fluid valve 52, the check valve 53, the return water tee connector 54, and the return water connector 55 are connected sequentially through pipelines to realize water flow control of the return water circuit 5; when the return water circuit 5 is working, the welding clamp water of the welding workstation body flows into the return water circuit from the return water connector 55. In circuit 5, water flows out from one end of the return water ball valve 51, thus providing a return water pipeline and corresponding return water control for the cooling circulation water of the welding clamp; the second water fluid valve 52 can realize the water flow control of return water circuit 5 to control its flow rate; the one-way valve 53 realizes the one-way flow of water in return water circuit 5, preventing the water flow from reverse circulation. For example, when the welding clamp is disassembled or when there is a leak in the inlet water circuit 4, resulting in a decrease in inlet water pressure, it can effectively prevent the water flow from reverse in return water circuit 5, thus improving the reliability of equipment operation. The return water ball valve 51, return water tee connector 54, and return water connector 55 are all located on the outside of the housing 1 for easy connection to water sources and water-using equipment. This allows users to connect and use the equipment without opening the housing 1. The return water ball valve 51 enables the regulation and control of the water flow and pressure in the return water circuit 5, facilitating user disassembly and assembly of the equipment. The return water tee connector 54 can provide additional return water lines, providing cooling water circulation branches for more water-using equipment. Similarly, one or more return water tee connectors 54 can be provided. The specific number of return water tee connectors 54 can be adjusted according to the user's specific needs. There is no limit to the number of return water tee connectors 54 provided here.

[0033] In the box-type visual water-air unit provided in Embodiment 1 of this utility model, as a further design improvement, the return water path 5 also includes: a return water tee 56 and a water pumping cylinder 57. The return water tee 56 is located between the one-way valve 53 and the return water tee connector 54. The water pumping cylinder 57 is connected to the return water tee 56 through a pipeline to realize the water flow control of the return water path 5. The water pumping cylinder 57 provides sufficient suction to the return water path 5 to prevent water from flowing out of the return water path 5 when the welding clamp connected to the return water path 5 is disassembled, installed, or replaced for maintenance. This avoids water overflow. In the prior art, even if the water supply system is turned off when the welding clamp is maintained or replaced, water will still flow out of the pipeline. The water pumping cylinder 57 effectively solves the problem of water overflow, which is conducive to the cleanliness of the production site and avoids damage to other electronic components and safety accidents. In order to control the water pumping cylinder 57, the air circuit system 3 also includes: an air circuit tee 33 and a solenoid valve 35. The air circuit tee 33 is located at one end of the air outlet of the air source triplet 32. The two ends of the solenoid valve 35 are connected to the water pumping cylinder 57 and the air circuit tee 33 respectively through pipelines to realize the action control of the water pumping cylinder 57. The solenoid valve 35 is used to control the air circuit system 3 to supply gas to the water pumping cylinder 57.

[0034] In the box-type visual water-air unit provided in Embodiment 1 of this utility model, more specifically, the water inlet path 4 includes: a water inlet ball valve 41, a filter 42, a first water fluid valve 43, a water flow sensor 44, a water inlet connector 45, and a water inlet tee connector 46. The water inlet ball valve 41, filter 42, first water fluid valve 43, water flow sensor 44, water inlet tee connector 46, and water inlet connector 45 are sequentially connected via pipelines to monitor and control the water flow in the water inlet path 4. Water flows in from the water inlet ball valve 41, passes through the aforementioned devices, and flows out from the water inlet connector 45. The water inlet connector 45 connects to the welding clamp water inlet of the welding workstation, providing cooling circulating water for the welding clamp during operation. The water inlet ball valve 41 controls the water flow in the water inlet path 4. The system controls the flow of water until it is completely shut off. The filter 42 purifies the incoming water, reducing the impact or pollution of impurities on the equipment and improving its lifespan and reliability. The first water flow valve 43 controls the water flow in the inlet 4 until it is completely shut off, facilitating automated and intelligent control. The water flow sensor 44 collects real-time information on the water flow rate and size in the inlet 4, allowing for real-time monitoring of the water flow status and improving operational reliability. This enables users to monitor the operating status of the water-using equipment and the water-air unit in real time. The inlet ball valve 41, inlet connector 45, and inlet tee connector 46 are all located on the outside of the housing 1 for easy connection to the water source and water-using equipment, allowing users to connect and use the equipment without opening the housing 1. Similarly, one or more inlet tee connectors 46 can be provided, and the specific number of inlet tee connectors 46 can be adjusted according to the user's specific needs; there is no limit to the number of inlet tee connectors 46 provided here. In the first embodiment of this utility model, the welding clamp control cabinet is connected through the inlet tee connector 46 and the return tee connector 54, which also provides a cooling circulating water channel for the welding clamp control cabinet, accelerates the heat dissipation of the equipment, and improves the working reliability of the welding clamp control cabinet.

[0035] In the box-type visualized water-gas unit provided in Embodiment 1 of this utility model, in order to improve the level of intelligence, the electrical control box 2 is electrically connected to the gas source triplet 32, the second water fluid valve 52, the first water fluid valve 43, and the water flow sensor 44 to realize the monitoring or control of the above-mentioned equipment. The information and control parameters of the above-mentioned equipment can be displayed and input and adjusted through the control screen 21, realizing the visualization of parameters in the water-gas unit and improving the level of intelligence; the electrical control box 2 can also be connected to an external control system to realize the input and output of physical quantity signals, and realize the remote automatic control of the water-gas unit or the comprehensive control of the production line.

[0036] The box-type visual water and air unit provided in Embodiment 1 of this utility model also includes: a support 6, with the box 1 set above the support 6 and mechanically connected to the support 6. The support 6 provides necessary support for the box 1 and facilitates movement. In this way, only the support 6 needs to be moved to realize the position change of the box 1 on the production site, which is convenient and quick.

[0037] The box-type visual water-air unit provided in Embodiment 1 of this utility model also includes: fixing buckles 7, wherein the air circuit system 3, water inlet circuit 4, water return circuit 5 and their components are all mechanically fixed to the fixing partition 13 by a number of fixing buckles 7.

[0038] In the box-type visual water and air unit provided in Embodiment 1 of this utility model, the box door 11 and the rear cover 12 are respectively hinged to the box body 1 to realize the opening and closing of the box door 11 and the rear cover 12. This facilitates the inspection or replacement and maintenance of the components inside the two cavities of the box body 1, ensures the normal operation of the water and air unit, improves the reliability of operation, and makes replacement and maintenance convenient.

[0039] The working process of the box-type visualized water-gas unit provided in Embodiment 1 of this utility model is as follows: The structure and layout of this utility model are reasonable. Gas enters the gas-using equipment sequentially through the gas ball valve 31 and the gas source triplet 32 ​​via pipelines. In the water inlet 4, one water inlet is connected sequentially through the water inlet ball valve 41, filter 42, first water flow valve 43, water flow sensor 44, water inlet tee connector 46, and water inlet connector 45 via pipelines, and then enters the water-using equipment (such as the welding clamp of a welding workstation). After the water-using equipment is circulated and cooled, the water flows out of the equipment and into the return water path 5 through the return water connector 55. It then passes through the return water tee connector 54, the return water tee connector 56, the check valve 53, the second water fluid valve 52, and finally flows out from the return water ball valve 51 into a water storage device such as a water tank, thus completing one water cycle. Another water path is connected to another water-using equipment (such as a welding clamp control cabinet) through the inlet tee connector 46 and the return water tee connector 54, providing a cooling water circulation path for other water-using equipment.

[0040] Example 2

[0041] Figure 8The diagram shows a front view of the box-type visual water-air unit provided in Embodiment 2 of this utility model. In Embodiment 2 of this utility model, the same parts as in Embodiment 1 are marked with the same reference numerals. The differences are described below. Compared with Embodiment 1, the box-type visual water-air unit provided in Embodiment 2 mainly reduces the use of the inlet tee connector 46 and the return tee connector 54, thereby reducing the number of parts and further saving costs. Embodiment 2 of this utility model is suitable for situations where only one circulating water path is required. In use, this circulating water path only needs to be connected to the return water connector 55 and the inlet water connector 45.

[0042] Compared with the prior art, the box-type visualized water and air unit provided in this utility model embodiment has a reasonable design and layout. Through the two-cavity structure design of the box 1, the water and air circuits are physically separated, achieving dry and wet separation and convenient and quick installation and movement. The water pumping cylinder 57 is used to avoid water overflow during the disassembly and replacement of water-using equipment. The electrical control box 2 with the control screen 21 realizes the visualization of the water and air unit, improves the level of intelligence and working reliability, and is convenient for operation, maintenance and movement.

[0043] The following points need to be explained:

[0044] (1) Unless otherwise defined, the same reference numerals in the embodiments of this utility model and the accompanying drawings have the same meaning.

[0045] (2) The accompanying drawings of this utility model embodiment only involve the structure involved in this utility model embodiment. Other structures can refer to the general design.

[0046] (3) For clarity, some structures in the drawings used to describe embodiments of the present invention may be enlarged or reduced, that is, these drawings are not drawn to actual scale.

[0047] (4) Where there is no conflict, the embodiments of this utility model and the features in the embodiments can be combined with each other to obtain new embodiments.

[0048] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the protection scope of the claims.

Claims

1. A cabinet type visualized water vapor unit characterized by, include: The enclosure (1), electrical control box (2), air system (3), water inlet (4), and water return (5) are provided. The enclosure (1) includes a door (11), a rear cover (12), and a fixed partition (13). The fixed partition (13) is located between the door (11) and the rear cover (12) and divides the enclosure (1) into two cavities. The air system (3), the water inlet (4), and the water return (5) are mechanically connected to the fixed partition (13) to achieve their installation and fixation. The air system (3) includes an air source triplet (32) and is located in one of the cavities. The two ends of the pipes of the gas system (3) extend from the box (1); the water inlet (4) and the water return (5) are both set in another cavity to achieve physical separation from the gas system (3), and the two ends of the pipes of the water inlet (4) and the water return (5) extend from the box (1) respectively; the electrical control box (2) is set on the box door (11) and is electrically connected to the gas system (3), the water inlet (4) and the water return (5) respectively to realize the acquisition and control of electrical signals of the gas system (3), the water inlet (4) and the water return (5).

2. The tank visualizing water vapor unit according to claim 1, characterized in that, The return water circuit (5) includes: a return water ball valve (51), a second water fluid valve (52), a check valve (53), a return water tee connector (54), and a return water connector (55); the return water ball valve (51), the second water fluid valve (52), the check valve (53), the return water tee connector (54), and the return water connector (55) are connected in sequence through pipelines to realize the water flow control of the return water circuit (5). The return water ball valve (51), the return water tee connector (54), and the return water connector (55) are all located on the outside of the housing (1) to facilitate the connection of water source and water-using equipment.

3. The box-type visual water vapor unit according to claim 2, characterized in that, The return water path (5) further includes: a return water tee (56) and a pumping cylinder (57). The return water tee (56) is located between the one-way valve (53) and the return water tee connector (54). The pumping cylinder (57) and the return water tee (56) are connected by a pipeline to realize the water flow control of the return water path (5). The air path system (3) further includes: an air path tee (33) and a solenoid valve (35). The two ends of the solenoid valve (35) are respectively connected to the pumping cylinder (57) and the air path tee (33) by pipelines to realize the action control of the pumping cylinder (57).

4. The tank visualizing water vapor unit according to claim 3, characterized in that, The gas system (3) also includes: a gas ball valve (31) and a gas connector (34). The gas ball valve (31), the gas source triplet (32), the gas tee (33), and the gas connector (34) are connected in sequence through pipelines to realize the control of the gas path. The gas ball valve (31) and the gas connector (34) are both located on the outside of the housing (1) to facilitate the connection of the gas source and the gas-using equipment.

5. The cabinet visual water vapor unit according to any one of claims 2-4, wherein, The water inlet path (4) includes: a water inlet ball valve (41), a filter (42), a first water fluid valve (43), a water flow sensor (44), a water inlet connector (45), and a water inlet tee connector (46). The water inlet ball valve (41), the filter (42), the first water fluid valve (43), the water flow sensor (44), the water inlet tee connector (46), and the water inlet connector (45) are connected in sequence through pipelines to monitor and control the water flow in the water inlet path (4). The water inlet ball valve (41), the water inlet connector (45), and the water inlet tee connector (46) are all located on the outside of the housing (1) to facilitate the connection of water sources and water-using equipment.

6. The tank visualizing water vapor unit according to claim 5, characterized in that, The electrical control box (2) is electrically connected to the gas source triplet (32), the second water fluid valve (52), the first water fluid valve (43), and the water flow sensor (44) to monitor or control the above-mentioned equipment.

7. The tank visualizing water vapor unit according to claim 6, characterized in that, The electrical control box (2) includes a control screen (21), which is a touch screen used to control the box-type visual water and gas unit and display information in real time.

8. The tank visualizing water vapor unit according to claim 1, characterized in that, Also includes: The bracket (6) is provided above the box (1) and is mechanically connected to the bracket (6).

9. The tank visualizing water vapor unit according to claim 1, characterized in that, Also includes: The gas system (3), the water inlet (4), and the water return (5) are all mechanically fixed to the fixed partition (13) by a number of the fixed buckles (7).

10. The cabinet visualization water vapor unit of claim 1, wherein, The door (11) and the back cover (12) are hinged to the box body (1) to enable the door (11) and the back cover (12) to open and close.