KR101056136B1 - Double Chamber Diaphragm - Google Patents

Abstract

The present invention relates to a double chamber diaphragm that can significantly increase the amount of air and the air pressure by using a double chamber divided into a first chamber 210 and a second chamber 220, and more specifically, the side chamber 110, A case housing 100 composed of a bottom plate 120 and a top plate 115; And a diaphragm 200 having the case housing 100 installed therein, wherein the diaphragm 200 is coupled to maintain airtightness with the bottom plate 120 of the case housing 100. A first chamber 210 to be formed; A core part 230 having a top and bottom convex shape provided at an upper center of the first chamber 210; A second chamber provided in an annular shape along the upper surface of the core portion 230 to form a closed space independent of the first chamber 210 and the upper surface is coupled to maintain the airtightness to the lower surface of the upper plate 115 220; And a transfer valve 240 provided in the core part 230 and opening and closing the plate 11 when the second chamber 220 is compressed to supply air from the second chamber 220 to the first chamber. The case housing 100 is provided in the bottom plate 120 to communicate with the first chamber 210 and when the first chamber 210 is compressed, the opening and closing plate 11 is opened and the first chamber ( First discharge valve 130 for discharging the air of the 210 to the outside; And provided on the side wall 110 to communicate with the second chamber 220, and when the second chamber 220 is expanded, the opening / closing plate 11 is opened to suck outside air to supply the second chamber 220. And a second suction valve 160, wherein when the core part 230 is raised, the first chamber 210 is expanded and the second chamber 220 is compressed, and the core part 230 is When descending, the first chamber 210 is compressed and the second chamber 220 is expanded.

Case housing, diaphragm, first chamber, second chamber, core part, first suction valve, second suction valve, first discharge valve, second discharge valve, opening and closing plate

Description

Double Chamber Diaphragm

The present invention relates to a diaphragm for generating compressed air, and more particularly, by using a two-chambered double chamber structure, the compressed air generated per unit time is significantly increased while maintaining a compact size.

The operating principle of the pump using a conventional diaphragm is that the diaphragm 2 repeats compression and expansion according to the connecting rod 1 reciprocating as shown in FIG. 1, and the diaphragm 2 expands. If the diaphragm 2 is compressed, outside air flows into the diaphragm 2 when the opening / closing plate 4 blocking the intake valve 3 is opened. As the opening and closing plate 6 blocking the valve 5 is opened, the compressed air inside the diaphragm 2 is discharged through the discharge valve 5.

In order to increase the amount of air discharged per unit time using the conventional diaphragm 2, the RPM of the power unit is increased to increase the number of times of compression / expansion of the diaphragm 2 per unit time or the diaphragm 200. ) Inevitably, the size (volume) of the body itself must be enlarged, but depending on the use of the diaphragm 2, the volume may not be enlarged indefinitely (when compact compact size is required). Appropriate RPM is specified for each product, so it is impossible to increase RPM indefinitely.

Therefore, in the case of a small product requiring high-pressure discharge air, there is a problem that the conventional diaphragm does not meet the requirements of the product.

The present invention, which was created to solve the above problems, greatly increases the amount of air discharged per unit time while minimizing the volume of the diaphragm to be applied in various fields to small products and other various products requiring high pressure blowing air. It is an object of the present invention to provide a new concept dual chamber diaphragm.

Technical composition of the present invention created to solve the above problems is as follows.

The present invention comprises a case housing 100 consisting of a side wall 110, a bottom plate 120 and the top plate 115; And a diaphragm 200 having the case housing 100 installed therein.

The diaphragm 200 may include a first chamber 210 coupled to maintain airtightness with the bottom plate 120 of the case housing 100; A core part 230 having a top and bottom convex shape provided at an upper center of the first chamber 210; A second chamber provided in an annular shape along the upper surface of the core portion 230 to form a closed space independent of the first chamber 210 and the upper surface is coupled to maintain the airtightness to the lower surface of the upper plate 115 220; And a transfer valve 240 provided in the core part 230 and opening and closing the plate 11 when the second chamber 220 is compressed to supply air from the second chamber 220 to the first chamber. The case housing 100 is provided in the bottom plate 120 to communicate with the first chamber 210, and when the first chamber 210 is compressed, the opening and closing plate 11 is opened to open the first chamber. First discharge valve 130 for discharging the air of the 210 to the outside; And provided on the side wall 110 to communicate with the second chamber 220, and when the second chamber 220 is expanded, the opening / closing plate 11 is opened to suck outside air to supply the second chamber 220. And a second suction valve 160, wherein when the core part 230 is raised, the first chamber 210 is expanded and the second chamber 220 is compressed, and the core part 230 is When descending, the first chamber 210 is compressed and the second chamber 220 is expanded.

In addition, the diaphragm 200 of the present invention, the first chamber 210 is coupled to maintain the airtightness to the bottom plate 120 of the case housing 100; A core part 230 having a top and bottom convex shape provided at an upper center of the first chamber 210; And an annular shape formed along an upper surface of the core part 230 to form a closed space independent of the first chamber 210, and an upper surface of which is coupled to maintain an airtightness on a lower surface of the upper plate 115. Two chambers 220; The case housing 100 is provided in the bottom plate 120 to communicate with the first chamber 210 and when the first chamber 210 is expanded, the opening and closing plate 11 is opened to suck the outside air. A first suction valve 150 supplied to the first chamber 210; Is provided on the bottom plate 120 and communicates with the first chamber 210 and when the first chamber 210 is compressed to open and close the opening plate 11 to discharge the air of the first chamber 210 to the outside First discharge valve 130; Is provided on the side wall 110 to communicate with the second chamber 220, when the second chamber 220 is expanded, the opening and closing plate 11 is opened to suck the outside air to supply to the second chamber 220 Two suction valves 160; And, the side wall 110 is provided in communication with the second chamber 220 and when the second chamber 220 is compressed, the opening and closing plate 11 is opened to discharge the air of the second chamber 220 to the outside A second discharge valve 140; The first chamber 210 is expanded and the second chamber 220 is compressed when the core part 230 is raised, and the first chamber 210 when the core part 230 is lowered. Is compressed and the second chamber 220 is expanded.

According to the configuration of the present invention it is possible to discharge the high-pressure blowing air by dramatically increasing the amount of air discharged per unit time while minimizing the volume of the diaphragm.

That is, in the embodiment shown in FIG. 2 or FIG. 3, when the core part 230 rises, air is simultaneously sucked into the first chamber 210 through the first suction valve 150 and the transfer valve 240, and suction is performed. When the core unit 230 is lowered, the discharged air is discharged through the first discharge valve 130. More air is introduced into the first chamber 210 when the upper portion of the core unit 230 is lowered, thereby lowering the core unit 230. When more air can be discharged through the first discharge valve 130, the amount of air discharged and the air pressure can be significantly increased.

In particular, the air flowing into the first chamber 210 through the transfer valve 240 is supplied to the first chamber 210 in a compressed state in the second chamber 220 so that more air is discharged at a given time and volume. The first chamber 210 may be supplied and discharged.

In the embodiment shown in FIG. 4, when the core part 230 rises, air in the second chamber 220 is compressed and discharged through the second discharge valve 140, and the core part 230 descends. The air inside the first chamber 210 is compressed and discharged through the first discharge valve 130.

That is, the compressed air is continuously discharged over one cycle, and thus more compressed air can be discharged at a given time and volume, thereby significantly increasing the amount of air and the air pressure.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the case of the opening and closing plate 11, the same reference numerals are given to simplify the reference numerals.

2, the diaphragm 200 installed in the case housing 100 and the case housing 100 including the side wall 110, the bottom plate 120, and the top plate 115 is provided. A dual chamber diaphragm is shown.

The material of the diaphragm 200 is not particularly limited, but a material such as a soft polyurethane, teflon, or silicon is preferably used, and the case housing 100 is made of a hard material unlike the diaphragm 200. It must be able to maintain its shape.

The diaphragm 200 includes a first chamber 210, a core part 230, a second chamber 220, and a transfer valve 240.

The first chamber 210 is coupled to maintain airtightness with the bottom plate 120 of the case housing 100.

The core portion 230 is provided at the upper center of the first chamber 210 and has a convex shape on the upper and lower surfaces thereof, so that the thickness of the core portion 230 is greater than that of the other parts of the diaphragm 200.

The second chamber 220 is provided in an annular shape along the upper surface of the core portion 230, and forms a closed space independent of the first chamber 210, and the upper surface of the second chamber 220 is the upper plate 115. It is coupled to maintain the airtightness on the lower surface of the.

The transfer valve 240 is provided in the core part 230. When the second chamber 220 is compressed, the opening / closing plate 11 opens toward the first chamber 210 while the air of the second chamber 220 is opened. Is supplied to the first chamber 210, and when the second chamber 220 is expanded, the opening and closing plate 11 of the open transfer valve 240 is closed again so that the air of the first chamber 210 is the second chamber 220. You won't be able to cross.

The first discharge valve 130 is provided on the bottom plate 120 of the case housing 100 to communicate with the first chamber 210. When the first chamber 210 is compressed, the opening and closing plate 11 is directed toward the outside. While opening, the air of the first chamber 210 is discharged to the outside, and when the first chamber 210 is expanded, the opening / closing plate 11 of the opened first discharge valve 130 is closed again so that the external air is discharged to the first discharge valve ( It does not flow into the first chamber 210 through 130.

The second suction valve 160 is provided on the side wall 110 to communicate with the second chamber 220. When the second chamber 220 is expanded, the opening and closing plate 11 opens toward the inside and sucks outside air. When the second chamber 220 is supplied to the second chamber 220 and the second chamber 220 is compressed, the opening / closing plate 11 of the second suction valve 160 is closed again so that the air inside the second chamber 220 is not discharged to the outside. Do not.

In the diaphragm as shown in FIG. 2, when the core portion 230 rises, the first chamber 210 expands and the second chamber 220 compresses, and when the core portion 230 descends, the first chamber 210 is compressed and the second chamber 220 is expanded.

That is, when the core 230 is raised, the first chamber 210 expands and the second chamber 220 is compressed, and the second chamber 220 is compressed from the second chamber 220 to the first chamber 210 through the transfer valve 240. Air is supplied.

When the core 230 is lowered again, the first chamber 210 is compressed and the second chamber 220 is expanded, and the air inside the first chamber 210 is discharged to the outside through the first discharge valve 130. Outside air is introduced into the second chamber 220 through the second suction valve 160.

When this process is repeated, the first chamber 210 may be discharged by receiving compressed air from the second chamber 220 to discharge more air.

3 is a case in which the first suction valve 150 is added to the bottom plate 120 as another embodiment of the present invention, the first suction valve 150 is the opening and closing plate 11 when the first chamber 210 is expanded; ) Is opened and sucks outside air to supply to the first chamber 210, and when the first chamber 210 is compressed, the opening and closing plate 11 of the first chamber 210 is closed again to close the first chamber 210. The air inside is not discharged to the outside through the first suction valve 150.

As such, when the first suction valve 150 is added, when the core part 230 rises, the first chamber 210 expands and the second chamber 220 is compressed, so that the first suction valve 150 and the transfer valve ( At the same time, air is introduced into the first chamber 210 through the 240, thereby securing and discharging more air.

Figure 4 shows another embodiment of the present invention.

In the case of FIG. 4, as in FIG. 3, the case housing 100 includes the side wall 110 and the bottom plate 120, and the diaphragm 200 installed inside the case housing 100.

Diaphragm 200 is composed of a first chamber 210, a core portion 230, and a second chamber 220, the difference from the case of Figure 3 is that there is no transfer valve 240, the rest other than Since the components are the same, separate descriptions are omitted.

The case housing 100 includes a first suction valve 150, a first discharge valve 130, a second suction valve 160, and a second discharge valve 140, which is different from FIG. 3 in the second discharge valve. 140 is further provided, and the rest of the other components are the same, and the redundant description thereof will be omitted.

The second discharge valve 140 is provided on the side wall 110 to communicate with the second chamber 220 and when the second chamber 220 is compressed, the opening / closing plate 11 is opened to the outside and the air of the second chamber 220 is opened. Will be discharged to the outside.

Another embodiment of the present invention as shown in FIG. 4 operates as follows.

As the core part 230 rises, the first chamber 210 is expanded and the second chamber 220 is compressed, and external air flows into the first chamber 210 through the first suction valve 150, and the second chamber 220 is compressed. The air inside the second chamber 220 is discharged to the outside through the discharge valve 140, when the core 230 is lowered, the first chamber 210 is compressed and the second chamber 220 is expanded while the first chamber 220 is expanded. The air inside the first chamber 210 is discharged to the outside through the discharge valve 130, and the outside air flows into the second chamber 220 through the second suction valve 160.

If this process is repeated, the air is discharged through the second discharge valve 140 in the process of raising the core unit 230 and the air is discharged through the first discharge valve 130 in the process of lowering the core unit 230. Is discharged.

Therefore, the air is sucked and discharged at the same time as the core portion 230 moves up and down to discharge more air.

The air discharged through the first discharge valve 130 and the second discharge valve 140 may be collected in a single pipe. As shown in FIG. 4, when the discharge pipe 300 is additionally installed, the first discharge valve ( 130 and the air discharged from the second discharge valve 140 can be collected together and discharged together.

In the case of the present invention, it is also possible to manually operate the elevating of the core unit 230, but in order to increase the efficiency, it is more preferable to use the apparatus as shown in FIG.

The power unit 410 generates a driving force, and various electric motors (direct current, alternating current), hydraulic motors, ultrasonic motors (piezo motors), and the like may be used.

The eccentric cam 420 is connected to the power shaft of the power unit 410 is to convert the rotary motion into a vertical reciprocating motion.

The connecting rod 430 is connected to the eccentric cam 420 to vertically reciprocate, and the core portion 230 is coupled to the lower end of the connecting rod 430.

Therefore, the connecting rod 430 connected to the eccentric cam 420 in conjunction with the rotation of the power unit 410 is to raise and lower the core portion 230 while reciprocating up and down.

Although the technical spirit of the present invention has been described with reference to specific embodiments of the present invention as described above, the scope of protection of the present invention is not necessarily limited to these embodiments, and various designs may be made without changing the technical spirit of the present invention. Changes, additions or deletions of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

1 shows the principle of operation of a conventional diaphragm.

2 is a cross-sectional structure of a specific embodiment of the present invention.

3 is a cross-sectional structure of another specific embodiment of the present invention.

Figure 4 is a cross-sectional structure of another specific embodiment of the present invention.

5 shows a power plant that may additionally be provided.

<Description of the symbols for the main parts of the drawings>

100: case housing

110: side wall

120: bottom plate

130: first discharge valve

140: second discharge valve

150: first suction valve

160: second suction valve

200: diaphragm

210: first chamber

220: second chamber

230: Core part

240: feed valve

300: discharge pipe

410: power unit

420: Eccentric cam

430: connecting rod

11: Opening and shutting board

Claims (5)

A case housing (100) consisting of a side wall (110), a bottom plate (120) and a top plate (115) having an open center portion; And, A diaphragm 200 installed inside the case housing 100; Consists of including The diaphragm 200, A first chamber 210 coupled to the bottom plate 120 of the case housing 100 to maintain airtightness; A core part 230 having a top and bottom convex shape provided at an upper center of the first chamber 210; A second chamber provided in an annular shape along the upper surface of the core portion 230 to form a closed space independent of the first chamber 210 and the upper surface is coupled to maintain the airtightness to the lower surface of the upper plate 115 220; And, A transfer valve 240 provided in the core part 230 and supplying air of the second chamber 220 to the first chamber 210 when the second chamber 220 is compressed and the opening / closing plate 11 is opened; Consisting of, The case housing 100, It is provided on the bottom plate 120 and communicates with the first chamber 210 and when the first chamber 210 is compressed, the opening and closing plate 11 is opened to release the air of the first chamber 210 to the outside The first discharge valve 130; And, Is provided on the side wall 110 to communicate with the second chamber 220, when the second chamber 220 is expanded, the opening and closing plate 11 is opened to suck the outside air to supply to the second chamber 220 Two suction valves 160; Including, When the core portion 230 is raised, the first chamber 210 is expanded and the second chamber 220 is compressed. When the core portion 230 is lowered, the first chamber 210 is compressed and the Double chamber diaphragm, characterized in that the second chamber 220 is expanded. A case housing (100) consisting of a side wall (110), a bottom plate (120) and a top plate (115) having an open center portion; And, A diaphragm 200 installed inside the case housing 100; Consists of including The diaphragm 200, A first chamber 210 coupled to the bottom plate 120 of the case housing 100 to maintain airtightness; A core part 230 having a top and bottom convex shape provided at an upper center of the first chamber 210; And, A second chamber provided in an annular shape along the upper surface of the core portion 230 to form a closed space independent of the first chamber 210 and the upper surface is coupled to maintain the airtightness to the lower surface of the upper plate 115 220; Consisting of, The case housing 100, The bottom plate 120 is provided to communicate with the first chamber 210 and when the first chamber 210 is expanded, the opening and closing plate 11 opens and sucks outside air to supply the first chamber 210. First suction valve 150; Is provided on the bottom plate 120 and communicates with the first chamber 210 and when the first chamber 210 is compressed to open and close the opening plate 11 to discharge the air of the first chamber 210 to the outside First discharge valve 130; Is provided on the side wall 110 to communicate with the second chamber 220, when the second chamber 220 is expanded, the opening and closing plate 11 is opened to suck the outside air to supply to the second chamber 220 Two suction valves 160; And, Is provided on the side wall 110 to communicate with the second chamber 220 and when the second chamber 220 is compressed opening and closing plate 11 is opened to discharge the air of the second chamber 220 to the outside 2 discharge valve 140; Including, When the core portion 230 is raised, the first chamber 210 is expanded and the second chamber 220 is compressed. When the core portion 230 is lowered, the first chamber 210 is compressed and the Double chamber diaphragm, characterized in that the second chamber 220 is expanded. In claim 1, The bottom plate 120 is provided to communicate with the first chamber 210 and when the first chamber 210 is expanded, the opening and closing plate 11 opens and sucks outside air to supply the first chamber 210. First suction valve 150; Double chamber diaphragm characterized in that it further comprises. 3. The method of claim 2, A discharge pipe 300 for collecting and discharging the air discharged from the first discharge valve 130 and the second discharge valve 140 into one; Double chamber diaphragm characterized in that it further comprises. The method according to any one of claims 1 to 4, A power unit 410 for generating a driving force; An eccentric cam (420) connected to the power shaft of the power unit (410) for converting rotational movement into a vertical reciprocating motion; And, A connecting rod 430 connected to the eccentric cam 420 to perform a vertical reciprocating motion; More is included, Dual-chamber diaphragm, characterized in that the core portion 230 is coupled to the lower end of the connecting rod (430).

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