KR101131922B1 - Diaphragm with Upper and Lower Chamber - Google Patents

Abstract

The present invention provides an inner space and a housing case (100) having an opening (11) formed in the lower center to communicate the inner space and the outside; And a soft diaphragm 200 installed in the inner space of the housing case 100 to reciprocate up and down, wherein the diaphragm 200 defines an inner space edge of the housing case 100. The upper film 210 is fixed to maintain the air tightness along; A lower film 220 which is continuously extended downward from the lower surface of the upper film 210 and fixed to maintain airtightness along the edge of the opening 11 of the housing case 100; An upper chamber 230 formed as a space between an upper surface of the upper layer 210 and an upper surface of an inner space of the housing case 100 when the upper layer 210 descends; And an annular lower chamber 240 formed as a space between the upper layer 210, the lower layer 220, and a lower surface of the inner space of the housing case 100. It relates to a diaphragm provided.

Description

Diaphragm with Upper and Lower Chamber

The present invention relates to a diaphragm for generating compressed air, and more particularly, by using the compression and expansion process of the upper chamber and the lower chamber partitioned by the diaphragm installed in the housing case to allow the intake and discharge of air at the same time. Its purpose is to drastically increase the amount of intake and discharge and to minimize operating noise.

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 2 ) Inevitably, the size (volume) of the body itself must be enlarged, but the size of the diaphragm 2 may not be enlarged indefinitely depending on the intended use of the diaphragm (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.

In addition, the existing diaphragm is intended to quantitatively inhale and discharge the fluid containing most of the air. The focus is only on the purpose, there is a limit that can not be applied to such a conventional diaphragm in the field requiring a strong suction force or a strong discharge force.

The present invention, devised to solve the above problems, not only dramatically increases the amount of air discharged per unit time, but also provides a new structure of diaphragm that can provide a strong intake force, while at the same time simplifying and operating the structure. It aims to provide a new concept of diaphragm that can be applied in various ways to small products requiring strong suction power or high-pressure blowing air by minimizing noise, as well as large products and various other products.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention provides an inner space and a housing case (100) having an opening (11) formed in the lower center to communicate the inner space and the outside; And a soft diaphragm 200 installed in the inner space of the housing case 100 to reciprocate up and down.

The diaphragm 200 has an upper film 210 fixedly installed to maintain airtightness along an edge of the inner space of the housing case 100; A lower film 220 which is continuously extended downward from the lower surface of the upper film 210 and fixed to maintain airtightness along the edge of the opening 11 of the housing case 100; An upper chamber 230 formed as a space between an upper surface of the upper layer 210 and an upper surface of an inner space of the housing case 100 when the upper layer 210 descends; And an annular lower chamber 240 formed as a space between the upper layer 210, the lower layer 220, and a lower surface of the inner space of the housing case 100.

In addition, the first intake port 110 penetrates the housing case 100 to the upper chamber 230; A first intake valve 115 installed in the first intake port 110 to open when the upper layer 210 descends and close when the upper layer 210 rises; A second intake port 120 penetrating through the housing case 100 and connected to the lower chamber 240; A second intake valve 125 installed in the second intake 120 and closed when the upper membrane 210 descends and opened when the upper membrane 210 rises; A first exhaust port 130 penetrating through the housing case 100 and connected to the upper chamber 230; A first exhaust valve 135 installed in the first exhaust port 130 and closed when the upper layer 210 descends and opened when the upper layer 210 rises; A second exhaust port 140 connected to the lower chamber 240 through the housing case 100; And a second exhaust valve 145 installed in the second exhaust port 140 and opened when the upper layer 210 descends and closed when the upper layer 210 rises.

According to the configuration of the present invention it is possible to provide a new structure of the diaphragm that can not only significantly increase the amount of air discharged per unit time, but also provide a strong suction force.

In other words, when the diaphragm 200 is lowered, the first intake valve 115 is opened and air is introduced into the upper chamber 230, and the first exhaust valve 135 is closed to close the first exhaust port 130. The inflow of air through is blocked. In addition, as the diaphragm 200 descends, the second exhaust valve 145 is opened to discharge air through the second exhaust port 140, and the second intake valve 125 is closed to close the second intake port 120. The release of air through the air is cut off.

When the diaphragm 200 rises, air is discharged through the first exhaust port 130 while the first exhaust valve 135 is opened, and the first intake valve 115 is closed to pass through the first intake port 110. Air exhaust is shut off. In addition, as the diaphragm 200 rises, air is introduced into the lower chamber 240 through the second inlet 120 while the second intake valve 125 is opened, and the second exhaust valve 145 is closed. The inflow of air through the double vent 140 is blocked.

In the process of descending the diaphragm 200, the intake and discharge of the air is made at the same time, the intake and discharge of the air is made at the same time, even in the process of the diaphragm 200 is raised. Therefore, the suction efficiency and the discharge efficiency can be significantly increased compared to the external size of the diaphragm itself.

In addition, the present invention can be applied to a variety of products, as well as a large product and a variety of other products that require a strong suction force or high-pressure blowing air by simplifying the structure and minimize the operating noise.

1 is a cross-sectional structure of a conventional diaphragm device.
Figure 2 is a cross-sectional structure of a specific embodiment of the present invention, (a) shows the process of the diaphragm 200 descends, (b) shows the process of the diaphragm 200 is raised, (c) the diaphragm The state in which the 200 is completely raised so that the upper chamber 230 is not formed is illustrated.
3 illustrates a case in which a power unit 310, an eccentric cam unit 320, and a connecting rod 330 are added as another specific embodiment of the present invention.
4 illustrates a case where an intake body 410, an intake pipe 420, and a filter 430 are added as another specific embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a cross-sectional structure of a specific embodiment of the present invention, (a) shows the process of the diaphragm 200 descends, (b) shows the process of the diaphragm 200 is raised, (c) the diaphragm The state in which the 200 is completely raised so that the upper chamber 230 is not formed is illustrated.

An inner space for accommodating the diaphragm 200 is provided inside the housing case 100, and an opening 11 communicating with the outside is formed in the lower center of the housing case 100.

The diaphragm 200 is made of a flexible soft material and installed in the inner space of the housing case 100 to reciprocate up and down.

The diaphragm 200 may be divided into an upper layer 210 part and a lower layer 220 part, and the upper layer 210 and the lower layer 220 are formed as one body rather than being separated from each other. .

As shown in FIG. 2, the upper layer 210 is fixedly installed along the edge of the inner space of the housing case 100, and the lower layer 220 is continuously downward from the lower surface of the upper layer 210. It is extended and fixed to maintain airtightness along the edge of the opening 11 of the housing case 100.

The upper chamber 230 is a space formed between the upper surface of the upper film 210 and the upper surface of the inner space of the housing case 100 when the upper film 210 is lowered.

The lower chamber 240 is an annular space formed by the upper layer 210, the lower layer 220, and a lower surface of the inner space of the housing case 100.

The first intake port 110 is connected to the upper chamber 230 through the housing case 100 to serve as an inlet of air sucked into the upper chamber 230.

The first intake valve 115 is installed in the first intake port 110, and is opened when the upper membrane 210 is lowered and closed when the upper membrane 210 is raised, the on / off valve used for a general diaphragm. Similar to the structure.

The second intake 120 is connected to the lower chamber 240 through the housing case 100 to serve as an inlet of air sucked into the lower chamber 240.

The second intake valve 125 is installed in the second intake port 120, and is closed when the upper membrane 210 is lowered and closed when the upper membrane 210 is raised, the on / off valve used for a general diaphragm. It is similar in structure.

In FIG. 2, only the case where the second intake port 120 is branched from the middle portion of the first intake port 110 is illustrated. However, the second intake port 120 is not limited to this case, and is not limited to the first intake port 110. May be formed.

The first exhaust port 130 penetrates through the housing case 100 and is connected to the upper chamber 230 to serve as an outlet for discharging air inside the upper chamber 230 to the outside.

The first exhaust valve 135 is installed in the first exhaust port 130 and is closed when the upper membrane 210 is lowered and opened when the upper membrane 210 is raised. The structure of the opening / closing valve used for a general diaphragm is as follows. Similar to

The second exhaust pipe 140 is connected to the lower chamber 240 through the housing case 100 and serves as an outlet for discharging air inside the lower chamber 240 to the outside.

The second exhaust valve 145 is installed in the second exhaust pipe 140 and is closed when the upper membrane 210 descends and is opened when the upper membrane 210 rises. The structure of the opening / closing valve used for a general diaphragm Similar to

FIG. 2 illustrates only a case in which the first exhaust port 130 and the second exhaust port 140 are connected to the outside air after being combined into one passage in the housing case 100, but the present invention is not necessarily limited thereto. 130 and the second exhaust vent 140 may not form a separate passage.

The upper film 210 of the diaphragm 200 has a dome shape with a central portion soaring, and the upper film 210 of the diaphragm 200 has a relatively thick thickness in comparison with other portions of the diaphragm 200. It is preferred to have, but is not necessarily limited to this form.

As such, when the central portion of the upper membrane 210 of the diaphragm 200 is formed thicker than other portions, the air inside the upper chamber 230 can be more surely compressed and discharged to the outside when the diaphragm 200 is raised. Even when the diaphragm 200 descends, the air inside the lower chamber 240 can be more surely compressed and discharged to the outside.

The upper surface of the inner space of the housing case 100 is recessed to correspond to the shape of the upper film 210 of the diaphragm 200. When the diaphragm 200 is raised, the upper film of the diaphragm 200 ( 210 is in contact with the upper surface of the inner space of the housing case 100, when the diaphragm 200 is lowered so that the upper film 210 of the diaphragm 200 away from the inner space of the housing case 100 do.

Figure 2 (a) shows the process of the diaphragm 200 is lowered, when the diaphragm 200 is lowered, the upper film 210 of the diaphragm 200 and the upper surface of the inner space of the housing case 100 As the upper chamber 230 is formed as a space therebetween and the volume of the upper chamber 230 is expanded, suction force is generated through the first intake port 110, so that the first intake valve 115 is opened and the upper chamber 230 is formed. Air enters inside. In this case, the first exhaust valve 135 is closed so that inflow of air through the first exhaust port 130 is blocked.

In addition, as the diaphragm 200 descends, the lower chamber 240 compresses the air in the lower chamber 240 as the volume decreases. The second exhaust valve 145 is opened by the compression force, thereby allowing the second exhaust valve ( Air exhaust through 140 is achieved. In this case, the second intake valve 125 is closed so that the air is discharged through the second intake 120.

As a result, while the diaphragm 200 descends, air is introduced into the upper chamber 230 through the first intake port 110 and at the same time, the air inside the lower chamber 240 is compressed through the second exhaust port 140. Is discharged. That is, the intake and exhaust of the air is made at the same time.

FIG. 2 (b) shows a process in which the diaphragm 200 rises. When the diaphragm 200 rises, the upper layer 210 of the diaphragm 200 and the upper surface of the inner space of the housing case 100 are shown. As the volume of the upper chamber 230 formed as a space therebetween decreases, the air inside the upper chamber 230 is compressed, and the first exhaust valve 135 is opened by this compression force, so that the air is discharged through the first exhaust mechanism 130. Is done. In this case, the first intake valve 115 is closed, and the air discharge through the first intake port 110 is blocked.

In addition, as the diaphragm 200 rises, the lower chamber 240 expands in volume to generate suction force through the second intake port 120, so that the second intake valve 125 is opened and lowered through the second intake port 120. Air is introduced into the chamber 240. In this case, the second exhaust valve 145 is closed so that inflow of air through the second exhaust port 140 is blocked.

As a result, air is introduced into the lower chamber 240 through the second inlet 120 while the diaphragm 200 is raised, and the air inside the upper chamber 230 is compressed through the first exhaust port 130. Is discharged. That is, the intake and exhaust of the air is made at the same time.

By integrating the processes of FIGS. 2A and 2B, the intake and discharge of the air are simultaneously performed while the diaphragm 200 descends, and the air of the diaphragm 200 rises. Suction and discharge take place simultaneously.

Therefore, the suction efficiency and the discharge efficiency can be significantly increased compared to the external size of the diaphragm itself, and the structure is simple, so that noise can be reduced.

3 illustrates a case in which a power unit 310, an eccentric cam unit 320, and a connecting rod 330 are added as another specific embodiment of the present invention.

The power unit 310 may include various types of motors or engines as a device for generating driving force.

One end of the connecting rod 330 is eccentrically connected to the eccentric cam portion 320 to the eccentric cam portion 320 that rotates in conjunction with the power unit 310.

Therefore, when the rotational movement of the eccentric cam portion 320 in conjunction with the power unit 310 is connected to the connecting rod 330 up and down reciprocating motion.

The other end of the connecting rod 330 passes through the central portion of the annular lower chamber 240 and is coupled to the center of the upper film 210 of the diaphragm 200.

Accordingly, when the power unit 310 operates, the diaphragm 200 inhales and compresses the external air while repeating the vertical movement in conjunction with this, and then discharges it.

In some cases, a plurality of eccentric cams 320 interlocked with one power unit 310 are arranged in a row, and each connecting rod 330 and the diaphragm 200 are operated at the same time for each of the eccentric cams 320. You can also

4 illustrates a case where an intake body 410, an intake pipe 420, and a filter 430 are added as another specific embodiment of the present invention.

The intake unit body 410 is coupled to the upper portion of the housing case 100, it is preferable to manufacture a structure that can be separated as necessary.

The intake pipe 420 has an inner passage 421 protruding from one side of the intake portion body 410 and the cross-sectional area is reduced toward the front end, the first intake 110 and the second intake 120 is intake The inner passage 421 of the intake pipe 420 passes through the interior of the body 410.

The filter 430 is installed inside the intake body 410 to remove foreign substances contained in the air sucked through the inner passage 421 of the intake pipe 420.

As such, when the intake pipe 420 is provided, the intake pipe 420 may be utilized in various ways as a vacuum suction device by using the high suction efficiency of the diaphragm 200.

As described above, specific embodiments of the present invention have been described with reference to the accompanying drawings, but the protection scope of the present invention is not necessarily limited to these embodiments, and various design changes and notifications are made within the scope of not changing the technical gist of the present invention. In the case of addition or deletion of technology, and simple numerical limitations, it is obvious that the scope of the present invention is included.

100: housing case
110: first intake
115: first intake valve
120: second intake
125: second intake valve
130: first exhaust
135: 1st exhaust valve
140: second exhaust port
145: the second exhaust valve
11: opening
200: diaphragm
210: upper layer
220: lower layer
230: upper chamber
240: lower chamber
310: power unit
320: eccentric cam part
330: connecting rod
410: intake body
420: intake pipe
421: internal passage
430: filter

Claims (7)

A housing case 100 having an inner space and an opening 11 formed at a lower center thereof in communication with the inner space; And,
A soft diaphragm 200 installed in the inner space of the housing case 100 to reciprocate up and down;
Consisting of
The diaphragm 200,
An upper film 210 fixedly installed to maintain airtightness along an edge of the inner space of the housing case 100;
A lower film 220 which is continuously extended downward from the lower surface of the upper film 210 and fixed to maintain airtightness along the edge of the opening 11 of the housing case 100;
An upper chamber 230 formed as a space between an upper surface of the upper layer 210 and an upper surface of an inner space of the housing case 100 when the upper layer 210 descends; And,
An annular lower chamber 240 formed as a space between the upper layer 210, the lower layer 220, and a lower surface of the inner space of the housing case 100;
≪ / RTI >
A first air inlet 110 connected to the upper chamber 230 through the housing case 100;
A first intake valve 115 installed in the first intake port 110 to open when the upper layer 210 descends and close when the upper layer 210 rises;
A second intake port 120 penetrating through the housing case 100 and connected to the lower chamber 240;
A second intake valve 125 installed in the second intake 120 and closed when the upper membrane 210 descends and opened when the upper membrane 210 rises;
A first exhaust port 130 penetrating through the housing case 100 and connected to the upper chamber 230;
A first exhaust valve 135 installed in the first exhaust port 130 and closed when the upper layer 210 descends and opened when the upper layer 210 rises;
A second exhaust port 140 connected to the lower chamber 240 through the housing case 100; And,
A second exhaust valve 145 installed in the second exhaust port 140 and opened when the upper layer 210 descends and closed when the upper layer 210 rises;
Diaphragm having an upper and lower chamber, characterized in that it comprises a. In claim 1,
The upper film 210 of the diaphragm 200 has a dome shape with a central portion soaring, and the upper film 210 of the diaphragm 200 has a central portion relatively to other portions of the diaphragm 200. Have a thick thickness,
The upper surface of the inner space of the housing case 100 is recessed to correspond to the shape of the upper film 210 of the diaphragm 200,
When the diaphragm 200 rises, the upper film 210 of the diaphragm 200 abuts the upper surface of the inner space of the housing case 100, and when the diaphragm 200 descends, the diaphragm ( The diaphragm having an upper and lower chambers, characterized in that the upper film 210 of the 200 is separated from the inner space of the housing case 100. In claim 1,
The second intake port 120 is a diaphragm having an upper and lower chambers, characterized in that formed in the middle portion of the first intake port (110). In claim 1,
The first and second exhaust pipes (130) and the second exhaust pipe (140) having a diaphragm having an upper and lower chambers, characterized in that joined to one passage in the housing case 100 and connected to the outside air. The method according to any one of claims 1 to 4,
A power unit 310 for generating a driving force;
An eccentric cam unit 320 that rotates in association with the power unit 310; And,
A connecting rod 330 connected to one side of the eccentric cam 420 so as to be eccentric to convert a rotational movement of the eccentric cam 320 into a vertical reciprocating motion;
More is included,
The other end of the connecting rod 330 is passed through the center of the annular lower chamber 240, the diaphragm having an upper chamber, characterized in that coupled to the center of the upper film 210 of the diaphragm 200 . The method according to any one of claims 1 to 4,
An intake part body 410 coupled to an upper portion of the housing case 100; And,
An intake pipe 420 having an inner passage 421 protruding from one side of the intake part body 410 and having a reduced cross-sectional area toward the tip;
Is included more,
The upper and lower chambers of the first intake port 110 and the second intake port 120 are connected to the inner passage 421 of the intake pipe 420 through the inside of the intake unit body 410. Equipped diaphragm. In claim 6,
The filter 430 to remove the foreign matter contained in the air sucked through the inner passage 421 of the intake pipe 420 inside the intake portion body 410;
Diaphragm having the upper and lower chambers, characterized in that is further provided.

Images