KR102205334B1 - Vacuum forming device for vacuum sensor protection by using membrane - Google Patents

Abstract

A vacuum forming device, comprising a passing flow passage where fluid passes, comprises: a sensing chamber connected to the passing flow passage; a vacuum sensor mounted inside the sensing chamber; a protection plate covering a sensing hole of the vacuum sensor; an elastic unit continuously pressurizing the protection plate to be closely attached to the sensing hole; and a membrane interposed between the sensing hole of the vacuum sensor and the protection plate. The vacuum forming device can protect the sensor from pollutants contained in the fluid.

Description

Vacuum forming device that protects vacuum sensor using membrane {VACUUM FORMING DEVICE FOR VACUUM SENSOR PROTECTION BY USING MEMBRANE}

The present invention relates to a vacuum forming apparatus including a vacuum sensor such as a vacuum forming apparatus and a vacuum pump, and more particularly, a vacuum sensor measuring a vacuum or extremely low pressure while protecting the vacuum sensor from a fluid passing through a pipe. It relates to a vacuum forming apparatus having a protective structure.

The operation for injecting a refrigerant into the air conditioner may go through processes such as installing a vacuum pump, discharging refrigerant, installing a refrigerant tank, and injecting refrigerant. In order to inject the refrigerant, the piping of the air conditioner must be made into a vacuum state, and in order to create a vacuum, a vacuum forming device is mounted on the path of the refrigerant discharge.

Korean Patent Laid-Open Publication No. 10-2009-0065010 relates to an automatic vacuum refrigerant injection device, wherein the automatic refrigerant injection device includes a vacuum forming device, and the vacuum forming device directly connects the vacuum pump and the manifold folder.

By means of the manifold, the vacuum forming apparatus may be exposed to the fluid during both the vacuum level maintenance and the refrigerant inflow process. However, the vacuum sensor measuring the pressure of the fluid in the vacuum forming apparatus is a very sensitive sensor and is necessary to maintain the degree of vacuum, but may be easily damaged during the inflow of the refrigerant.

In addition, contaminants contained in the refrigerant may flow into the vacuum sensor and cause a failure of the vacuum sensor. However, it is necessary to protect the vacuum sensor from contaminants contained in the refrigerant.

The present invention provides a vacuum forming apparatus capable of protecting a sensor from contaminants contained in a fluid while distinguishing a process of discharging and injecting a fluid such as a refrigerant.

In particular, a vacuum forming device capable of selectively separating the vacuum sensor from a fluid such as a refrigerant by blocking the sensing hole of the vacuum sensor from the outside, but temporarily exposing the sensing hole only in the process of forming a vacuum or extremely low pressure. Provides.

According to an exemplary embodiment of the present invention for achieving the objects of the present invention described above, a vacuum forming apparatus including a passage passage through which a fluid passes is a sensing chamber in communication with the passage passage, a vacuum sensor mounted in the sensing chamber, It includes a protective plate covering the sensing hole of the vacuum sensor, an elastic part that continuously presses the protective plate to adhere to the sensing hole, and a membrane interposed between the sensing hole and the protective plate of the vacuum sensor.

In the present specification, the vacuum forming apparatus is for forming a vacuum or completely discharging a fluid in a specific space, and may be applied to a vacuum pump as well as a vacuum forming apparatus, and may be applied to a refrigerant exchange apparatus for an air conditioner.

In a conventional vacuum forming apparatus such as a vacuum forming apparatus, a pipe connected to the outside and a sensor are directly connected so that the vacuum sensor is frequently damaged in the process of injecting a refrigerant. However, according to the present embodiment, in the process of replacing the refrigerant, the sensing hole of the vacuum sensor is basically blocked by the protection plate and the elastic part, and damage to the vacuum sensor can be prevented.

In addition, in the process of discharging the refrigerant, the protective plate temporarily retracts while forming a vacuum or extremely low pressure in the flow path, and in the process, it is possible to measure the extremely low pressure. However, at this time, even in the extremely low pressure state, the refrigerant may contain contaminants, and the membrane may prevent contaminants from flowing into the sensing hole even when the sensing hole is temporarily opened.

The membrane can be formed using a fibrous material such as a nonwoven fabric, and it prevents contaminants contained in the fluid from entering the vacuum sensor, and maintains an appropriate vacuum pressure so that the operation of the vacuum forming device is smoothly performed. have.

The membrane may be formed in various positions, for example, the membrane may be formed to cover the entrance of the sensing hole, and as another example, may be provided on the upper surface of the protective plate other than the vacuum sensor.

The membrane may be provided in the form of a replaceable cartridge rather than being adhered to or attached to a vacuum sensor or protective plate. For example, a membrane cartridge containing a membrane may be provided, and the membrane cartridge may enter the sensing chamber through a cartridge access path formed on one side of the aluminum body in which the sensing chamber is formed, and the cartridge access path can be blocked by the sealing cover. Can be provided.

The membrane cartridge may include a lower case that is in close contact with the lower portion of the membrane and an upper case that is coupled with the lower case to be in close contact with the upper portion of the membrane, and the lower surface of the lower case may be provided in a two-stage structure including an inclined surface.

Accordingly, the membrane cartridge may be in close contact with the lower portion while entering the cartridge access path, and the entire cartridge may rise along the inclined surface of the lower case while entering the cartridge to a certain extent so that the membrane adheres to the sensing hole of the vacuum sensor. If the cartridge is provided in a straight shape without an inclined surface, a vacuum sensor may be caught on the far end of the cartridge to prevent the cartridge from entering, and the membrane and the sensing hole may not be in close contact due to the frame structure surrounding the membrane. .

In addition, an angled or round fillet may be formed on the upper end of the protective plate corresponding to the lower case, and the protective plate may temporarily descend as the cartridge enters to allow the cartridge to enter.

The outer surface of the protective plate may be formed of Teflon, may be formed using Teflon, or may be coated with Teflon. In addition, the protective plate may further include a coupling protrusion protruding downward for binding with the elastic portion.

The sensing hole of the vacuum sensor can be designed to open while the protective plate is separated from the sensing hole when the pressure of the sensing chamber is relatively below the -13.0 ~ -14.7 PSI threshold, and for this purpose, the spring of the elastic part can be adjusted. At other pressures, it can be kept closed by the protective plate.

The vacuum forming apparatus of the present invention can protect the vacuum sensor from the inflow path of the fluid by separating the process of discharging and injecting a fluid such as a refrigerant, and can increase the sensitivity and life of the vacuum sensor.

In particular, in the process of discharging the refrigerant, the protective plate may temporarily retreat while forming a vacuum or extremely low pressure in the flow path. It can prevent inflow.

In addition, by adopting the simplest and most efficient structure to protect the vacuum sensor, practical application and manufacturing are easy, thereby providing an economical effect.

1 is a diagram illustrating a structure and a process of using a vacuum forming apparatus according to an embodiment of the present invention.
2 is a view for explaining the internal structure of the vacuum forming apparatus of FIG.
3 and 4 are views for explaining an operating mechanism of the vacuum forming apparatus of FIG. 1.
5 is a view for explaining the structure of a vacuum forming apparatus according to other embodiments of the present invention.
6 is a view for explaining an aluminum body of the vacuum forming apparatus according to an embodiment of the present invention.
7 is a view for explaining a vacuum sensor, a membrane cartridge and a protective plate located inside the aluminum body of FIG. 6.
FIG. 8 is a cross-sectional view illustrating the internal structure of the aluminum body of FIG. 6.
9 is a view for explaining a process of mounting the membrane cartridge in FIG. 8.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments. For reference, in the present description, the same numbers refer to substantially the same elements, and contents described in other drawings under the above rules may be cited and described, and contents that are deemed obvious to those skilled in the art or repeated may be omitted.

1 is a view for explaining the structure and use process of the vacuum forming apparatus according to an embodiment of the present invention, FIG. 2 is a view for explaining the internal structure of the vacuum forming apparatus of FIG. 1, FIGS. 3 and 4 Is a diagram for explaining an operating mechanism of the vacuum forming apparatus of FIG. 1.

1 to 4, the vacuum forming apparatus according to the present embodiment includes a main body 210 including a display and a pipe part 220 connected to a lower portion of the main body 210, and the pipe part 220 An air conditioner 10, a vacuum pump 20, or a refrigerant tank 30 may be connected to perform an operation for automatically replacing the refrigerant.

In the present embodiment, the display unit may be digitally displayed, and may be operated in a predetermined order through a power button, a pressure button, a mode change button, a refrigerant injection button, and the like disposed in front of the main body 210. In addition, a button for selecting a function or a unit of measurement, etc. may be included, and a button for adjusting brightness, etc. may be included.

For reference, in the present embodiment, a digital display unit is used, but alternatively, an analog display unit including a pointer needle may be used, or a combination display unit that simultaneously expresses a needle and a number may be used.

The body 210 may include an aluminum body 230 on which a vacuum sensor 240 is mounted, and a pipe 220 is connected around the aluminum body 230, and a display inside the body 210 Alternatively, the circuit unit may be connected.

Inside the aluminum body 230, a passage passage 232 through which a fluid such as a refrigerant can pass is formed, and a sensing chamber 234 is provided through a connection passage 236 formed in the middle to one side of the passage passage 232 Can be.

A spring 260 and a protective plate 250 are sequentially mounted from the connection passage 236 into the sensing chamber 234, and a vacuum sensor 240 is mounted thereon to form the sensing chamber 234.

The sensing chamber 234 may be blocked from the outside by the vacuum sensor 240, the sensing hole 242 faces downward and the sensing hole 242 may be covered by the membrane 272. In addition, the protective plate 250 may be in close contact with the entrance of the sensing hole 242 to block the sensing hole 242 by default (FIG. 3(a)). Then, when the protective plate 250 descends downward, the sensing hole 242 of the vacuum sensor 240 may be exposed, and even when the protective plate 250 descends, the membrane 272 basically covers the sensing hole 242. It can be blocked (Fig. 3 (b)).

Referring to (a) of FIG. 4, a user may open a valve and allow a fluid such as a refrigerant to enter the passage passage 232. In this case, the fluid F _high may be supplied to the passage passage 232 at a relatively high pressure, and may be supplied into the sensing chamber 234 through a connection passage 236 connected to the passage passage 232.

However, the protective plate 250 may be kept in close contact with the sensing hole 242 and the membrane 272 by the spring 260. In this case, the vacuum sensor 240 in the sensing chamber 234 is a fluid (F _high). ) And can be kept separate.

Referring to (b) of FIG. 4, when the refrigerant is discharged or the pressure of the passage passage 232 is reduced to a vacuum state, the passage passage 232 is filled with a fluid F _vacuum in an almost vacuum state, and the connection The sensing chamber 234 connected through the passage 236 may also be changed to vacuum or extremely low pressure. In this case, due to the difference in relative pressure, a gap may be temporarily formed between the inlet of the protective plate 250 and the sensing hole 242, and pressure measurement in an almost vacuum state is possible.

While the protective plate 250 opens and closes the entrance of the sensing hole 242, it is possible to continuously measure the pressure in an almost vacuum state. In this way, the protective plate 250 is temporarily separated from the vacuum sensor 240 only in the section where the vacuum sensor 240 is required to be used for pressure measurement, and in other sections, the protective plate 250 is in close contact with the vacuum sensor 240 It is possible to block the sensing hole 242 and protect the inside of the vacuum sensor 240.

However, even in a state of extremely low pressure, contaminants may be included in the refrigerant remaining in the pipe, and the membrane 272 may prevent contaminants from flowing into the sensing hole even when the sensing hole is temporarily opened.

Here, the membrane 272 may be formed using a fibrous material such as a nonwoven fabric. The membrane 272 may be provided with a material that allows air or fluid to pass but blocks contaminants, and a fibrous material such as a nonwoven fabric or other filter may be used. In addition, in the case of a fibrous material such as a nonwoven fabric, a slight buffer may be provided to buffer the impact between the protective plate and the vacuum sensor, or the vacuum forming apparatus may be smoothly operated by maintaining an appropriate vacuum pressure.

In this embodiment, the protective plate 250 may be formed using Teflon or the like having excellent durability. For example, by forming the outer surface of the protective plate 250 with a Teflon coating or the like, it is possible to prevent the protective plate 250 from being corroded or roughened by a refrigerant or the like. In addition, as described above, the non-woven membrane 272 may function to protect the Teflon coating.

In addition, the sensing hole 242 and the membrane 272 of the vacuum sensor 240 are in contact with the protective plate 250, and the protective plate 250 may be opened at a desired pressure by adjusting the elastic force of the spring 260. In particular, in this embodiment, the protective plate 250 may be designed to be separated from the sensing hole 242 when the pressure of the sensing chamber is less than the threshold value of -13.0 to -14.7 PSI relative to atmospheric pressure. Can be adjusted to have a spring load of about 158 g.

5 is a view for explaining the structure of a vacuum forming apparatus according to other embodiments of the present invention.

5, in providing the membrane 272 in the sensing hole of the vacuum sensor 240, the membrane 272 may be attached to the bottom of the sensing hole using a ring-shaped adhesive layer 274 (a) , The membrane 272' may be provided on the upper surface of the protective plate 250 instead of the vacuum sensor (b).

In addition, in the previous embodiment, a compression spring was used as the elastic part, but it is not necessarily limited to the spring, and a rubber elastic body 262 capable of closely contacting the protective plate 250 to the entrance of the sensing hole of the vacuum sensor 240 is fixed. Also, the protective plate 250 may be in close contact with the sensing hole by the rubber elastic body 262.

6 is a view for explaining the aluminum body of the vacuum forming apparatus according to an embodiment of the present invention, FIG. 7 is a view for explaining a vacuum sensor, a membrane cartridge and a protective plate located inside the aluminum body of FIG. FIG. 8 is a cross-sectional view illustrating the internal structure of the aluminum body of FIG. 6, and FIG. 9 is a diagram illustrating a process of mounting the membrane cartridge in FIG. 8.

6 to 9, the vacuum forming apparatus according to the present embodiment may include a main body including a display and a pipe part connected to the lower part of the main body, and the pipe part may be connected to an air conditioner, a vacuum pump or a refrigerant tank. have.

The body may include an aluminum body 330 on which the vacuum sensor 340 is mounted, a pipe part is connected around the aluminum body 330, and the vacuum sensor 340 is connected to a display or circuit part inside the body. I can.

Inside the aluminum body 330, a sensing chamber connected to one side to a passage passage for the flow of refrigerant is provided, and a spring 360, a protective plate 350, a membrane cartridge 370, and a vacuum sensor 340 are inside the sensing chamber. It can be mounted in turn.

The upper part of the sensing chamber may be blocked by the vacuum sensor 340, and the sensing hole of the vacuum sensor 340 may be in contact with or separated from the membrane 372 of the membrane cartridge 370. For reference, in the previous embodiment, the membrane remains adhered to the sensing hole or the protective plate, but in this embodiment, it may be provided to be replaceable by the membrane cartridge 370.

The membrane cartridge 370 may include a lower case 376 in close contact with the lower portion of the membrane 372 and an upper case 378 in contact with the lower case 376 and coupled to the upper case 378 in close contact with the upper portion of the membrane 372. The bottom surface of the lower case 376 is provided in a two-stage structure with different thicknesses, and the stepped structures are connected by inclined surfaces.

A hole 377 is formed in the lower case 376 corresponding to the sensing hole of the vacuum sensor 340, and the upper surface of the protective plate 350 may be in close contact with the hole 377 of the lower case 376. The protective plate 350 is in close contact with the hole 377 of the lower case 376 and may basically indirectly block the sensing hole of the vacuum sensor 340. Then, when the protective plate 350 descends downward in the extremely low pressure state, the hole 377 of the lower case 376 may be exposed, and at the same time, the sensing hole of the vacuum sensor 340 may also be exposed. .

In addition, even when the protective plate 350 is lowered, the membrane 372 of the cartridge 370 can basically block contaminants and the like flowing into the sensing hole.

As shown, the coupling protrusion may protrude below the protective plate 350, and the outer surface of the coupling protrusion is inserted into the inside of the spring 360, thereby firmly maintaining a bonded state between the protective plate 350 and the spring 360. Can be maintained.

Referring to (a) of FIG. 9, a cartridge access path 336 through which the cartridge can enter the rear of the aluminum body 330 is formed, and the cartridge access path 336 is attached to the sealing cover 334 that is opened and closed by screwing. It may be provided so as to be blocked.

The cartridge 370 may be installed for the first time or may be replaced after a certain period of time, and for this purpose, the sealing cover 334 may be removed, and the cartridge access path 336 may be exposed. When the membrane cartridge 370 enters from the rear, it can be easily entered by the inclined guide surface formed up and down at the entrance of the cartridge access path 336, and the front of the cartridge 370 is formed relatively thin to facilitate easy access. Entry is possible (a).

At this time, while the membrane cartridge 370 enters the cartridge access path 336, it may enter in close contact with the lower portion, and in a state that enters to some extent, the entire cartridge 370 rises while riding the slope of the lower case 376 The membrane 372 may be further approached and fixed to the sensing hole of 340 (c). If the cartridge is provided in a straight shape without an inclined surface, a vacuum sensor may be caught on the far end of the cartridge to prevent entry of the cartridge, and due to the frame structure of the upper case 378 surrounding the membrane 372, the membrane (372) and the sensing hole may interfere with approaching each other.

In addition, an angled or round fillet may be formed on the upper end of the protective plate 350 corresponding to the fabric of the lower case 376. As the cartridge 370 enters, the protective plate 350 may be temporarily lowered by pressing the end of the cartridge 370, allowing the cartridge 370 to easily enter, and after the cartridge 370 completely enters The upper surface of the protection plate 350 may be in close contact with the hole position of the lower case 376.

As described above, although it has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can do it.

210: main body 230: aluminum body
232: passage passage 234: sensing chamber
240: vacuum sensor 250: protective plate
260: spring 272: membrane

Claims (8)

In the vacuum forming apparatus comprising a passage passage through which the fluid passes,
A sensing chamber in communication with the passage passage;
A vacuum sensor mounted in the sensing chamber;
A protective plate for blocking the sensing hole of the vacuum sensor from the passage passage;
An elastic part continuously pressing the protective plate; And
Includes; a membrane interposed between the sensing hole and the protective plate of the vacuum sensor,
And the elastic part presses the protection plate in a direction for blocking the sensing hole of the vacuum sensor from the passage passage. The method of claim 1,
The membrane is a vacuum forming apparatus, characterized in that formed using a fiber material. The method of claim 1,
The membrane is formed to cover the entrance of the sensing hole vacuum forming apparatus. The method of claim 1,
The membrane is a vacuum forming apparatus, characterized in that provided on the upper surface of the protective plate. delete delete delete delete

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