KR20150005096A - diaphragm type air pump - Google Patents

Abstract

The present invention relates to a diaphragm type air pump with a new shape, which can prevent the inflow of water flowing backward to an air exhaust pipe, can stably install a structure of preventing backflow, and can conveniently perform entire assembly. The diaphragm type air pump comprises: a body housing which forms the external appearance thereof and wherein an operating space is formed; a rolling plate which is placed inside the body housing, and performs vertical rolling by being rotated due to driving force of a motor; a diaphragm which is combined with the top of the rolling plate, and has multiple compression chambers that repeat compression and expansion due to the vertical rolling of the rolling plate; an air port where a discharge room communicating with each of the compression chambers of the diaphragm is formed, and a communicating hole for communicating the discharge room with an upper space is formed; a cover body which covers the top of the air port in order to form a suction room between the air port and an opposed surface, and where an air inlet tube communicating with the suction room, and an air outlet tube communicating with the discharge room protrude; and a backflow preventing member which is placed at an air inlet side of the air outlet tube between the air port and the cover body, in order to prevent the backflow of water through the air outlet tube while a flow path elastically opens or closes.

Description

A diaphragm type air pump

The present invention relates to a diaphragm type air pump, and more particularly, to a new type diaphragm type air pump that can be manufactured easily but can prevent water backflow as much as possible.

Generally, a diaphragm type air pump is a small-sized pump that pumps air by supplying diaphragm while repeating compression and expansion by driving a driving motor. The diaphragm type air pump is connected to various devices (for example, bidets, etc.) And in this connection, it has been disclosed in Korean Patent Publication No. 10-0739042, Korean Patent Publication No. 10-0901737, Japanese Patent Application Laid-Open No. 2003-56465, Japanese Patent Application Laid-Open No. 2004-239101 same.

FIG. 1 shows an internal structure of a conventional diaphragm type air pump 10. As can be seen from the figure, a conventional diaphragm type air pump 10 includes a body housing 11, a rolling plate 13 A diaphragm 14, an air port 15 having an air discharge pipe 15a, and a cover member 16 having an air suction pipe 16a.

That is, the inclined pin 23, which is inclined and eccentric from the center of the shaft 21 of the driving motor 20, revolves around the axis of the driving motor 20 by driving the driving motor 20, The rolling plate 13 coupled to the compression chamber 23 sequentially compresses and expands the respective compression chambers 14a of the diaphragm 14 while performing the upward and downward oscillating motion by the idle operation of the inclined fin 23, The air sucked into the chamber 14a or the air is discharged and the air discharged from the compression chamber 14a is discharged to the outside through the air discharge pipe 15a of the air port 15. [

However, in the case of an air pump used to improve the soil discharge of water among the conventional general diaphragm type air pump 10 described above, it is connected to the water supply valve 31 as shown in FIG. 2, When the operation of the diaphragm type air pump 10 is stopped, considering the supply of air to the valve 31, the water flows back from the water supply valve 31 and flows through the air discharge pipe 15a, A phenomenon in which the refrigerant is introduced into the compression chamber 14a is often generated and compression failure of the compression chamber 14a is caused thereby resulting in a problem that the air can not be pumped smoothly. Reference numeral 32 denotes a water tank.

Of course, among the respective portions of the diaphragm type air pump 10, the open-close membrane 14b having a pipe structure is protruded and formed on the air outflow side of the diaphragm 14, 15 to be inserted into the inlet of the air discharge pipe 15a, so that backflow of water from the air discharge pipe 15a can be prevented.

However, the conventional diaphragm type air pump 10 having such a structure is operated such that, when the pump stops operating, the opening closing membrane 14b is operated so as to be closed gradually, rather than closing the inlet of the air discharge pipe 15a promptly, There is a problem that water is infiltrated into the compression chamber 14a of the diaphragm 14 when the pressure coming in through the discharge pipe 15a is low, In the process of integrating the air port 15 and the cover body 16 with each other, a clearance is generated due to an incorrect coupling of the open-close film 14b, so that the backflow of water through the air discharge pipe 15a occurs There was a problem.

SUMMARY OF THE INVENTION It is an object of the present invention to prevent water from flowing back into the air discharge pipe into the diaphragm and to stably install a structure for preventing backflow. And to provide a diaphragm-type air pump according to a new form in which the entire assembly can be easily performed.

To achieve the above object, according to the present invention, there is provided a diaphragm type air pump, comprising: a body housing having an outer space and an operation space formed therein; A rolling plate disposed in the body housing and receiving a driving force of the motor to rotate in the up and down direction; A diaphragm having a plurality of compression chambers coupled to an upper end of the rolling plate and repeating compression and expansion by up and down movement of the rolling plate; An air port formed with a discharge chamber communicated with each compression chamber of the diaphragm and having a communication hole communicating the discharge chamber with the upper space; A cover member having an air inlet pipe communicated with the suction chamber and an air discharge pipe communicating with the discharge chamber protruded from the upper surface, the cover member being formed on an upper surface of the cover member so as to cover the upper end of the air port; And a backflow prevention member provided on an air inflow side of the air discharge pipe between the air port and the cover body to prevent backflow of water through the air discharge pipe while the flow passage is opened and closed elastically. do.

The backflow prevention member may include a fixed end coupled to the air port and an upper end extending upwardly from the fixed end by a discharge pressure of air discharged through the communication hole, And a resilient opening / closing end that maintains the state.

In addition, the fixed end of the backflow preventing member is formed in a stepped structure having an outer peripheral surface that is wider than the elastic opening closing end, and a press-fitting member is provided around the communication hole on the upper surface of the air port, And a contact jaw which is in contact with the upper surface of the fixed end constituting the backflow preventing member is provided on the bottom surface of the cover body, Thereby forming a recess.

In addition, the elasticity closing end of the backflow preventing member is formed to have a structure in which the upper ends thereof are in contact with each other while being axially moved toward the upper part.

A communication groove is formed in the inner circumferential surface of the discharge port of the air port so as to communicate with the inside of the compression chamber of the diaphragm. A plurality of cutouts are formed along the circumferential direction at a central portion of the diaphragm to surround the discharge chamber inner circumferential surface And the opening groove is formed so that the communication groove communicates with the discharge chamber when the air flows through the communication groove.

The diaphragm type air pump of the present invention as described above compensates for the problem of the diaphragm opening closing membrane and further provides a backflow preventing member at the air inflow side of the air discharge pipe, It is possible to prevent the backflow of water or air due to the backflow into the discharge chamber and the compression chamber, thereby preventing the initial pumping failure of the air pump when the air pump is restarted.

Further, the diaphragm type air pump of the present invention has a multi-stepped step structure in which the fixed end of the backflow prevention member is formed so as to correspond to the air port and the cover body so as to surround the air port and the cover body, So that it is possible to prevent the assembling failure at the time of assembling.

1 is a cross-sectional view illustrating an internal structure of a conventional diaphragm type air pump
Fig. 2 is a schematic view schematically showing an application state of the diaphragm type air pump
3 is an exploded view illustrating a structure of a diaphragm type air pump according to an embodiment of the present invention.
4 is a cross-sectional view illustrating an internal structure of a diaphragm type air pump according to an embodiment of the present invention.
5 is an enlarged view of the " A "
6 and 7 are perspective views illustrating an outer structure of a backflow prevention member constituting a diaphragm type air pump according to an embodiment of the present invention.
Fig. 8 is an enlarged view of the main part shown in Fig. 4 for explaining a state in which the backflow prevention member is operated in the " A "

Hereinafter, an embodiment of the diaphragm type air pump of the present invention will be described with reference to Figs. 3 to 8 attached hereto.

3 to 5 show the internal structure of the diaphragm type air pump according to the embodiment of the present invention.

(Hereinafter referred to as "air pump") 100 according to an embodiment of the present invention includes a body housing 110, a rolling plate 130, a diaphragm 140 , An air port (150), a cover member (160), and a backflow prevention member (170).

This will be described in more detail below for each configuration.

First, the body housing 110 is formed in a cylindrical shape having an upper opening and an operating space inside, which forms an outer appearance of the air pump 100 according to the embodiment of the present invention.

The shaft 21 of the driving motor 20 penetrates through the bottom surface of the body housing 110 and is inserted into the body housing 110. The driving motor 20 is coupled to a lower end of the body housing 110, As shown in FIG.

An eccentric shaft 22 is further provided on a shaft 21 of the driving motor 20 positioned in the body housing 110 and a shaft 22 is provided on the eccentric shaft 22. [ And an inclined fin 23 which is inclined with respect to the axial direction formed by the inclined fin 21 is additionally provided.

Accordingly, the tilting pin 23 revolves around the center of the shaft 21 of the driving motor 20 in a tilted state when the driving motor 20 is driven.

Next, the rolling plate 130 is positioned within the body housing 110, and receives a driving force of the driving motor 20 through the slant pins 22, thereby rotating and moving up and down.

The rolling plate 130 is formed in a hat shape having a downwardly inclined structure with a downward inclination toward a peripheral edge with respect to a center portion. A coupling hub 131, into which the inclined fin 22 is inserted, .

Next, the diaphragm 140 generates an air pumping force to force the air to be pumped.

The diaphragm 140 is coupled to the upper end of the rolling plate 130 and is formed of a rubber material and has a plurality of compression chambers 141 along the circumferential direction.

At this time, the compression chambers 141 are formed in the shape of a dome protruding to the bottom, and the coupling protrusions 142 are formed on the bottom surface of each compression chamber 141, Respectively.

That is, each of the compression chambers 141 of the diaphragm 140 is repeatedly compressed and expanded by the upward and downward movement of the rolling plate 130, thereby sucking air into the respective compression chambers 141 Alternatively, air in each of the compression chambers 141 is discharged.

In the embodiment of the present invention, the diaphragm 140 is accommodated in the diaphragm guide 120 as an example.

The diaphragm guide 120 is formed to have a partition wall 121 for accommodating the respective compression chambers 141 of the diaphragm 140 so that the compression chambers 141 can be stably compressed and expanded .

Of course, although not shown, the diaphragm guide 120 may be integrally formed at the upper end of the body housing 110.

Next, the air port 150 is configured to partition a space in the compression chamber 141 from a suction chamber 161 formed between the air port 150 and a cover 160 to be described later.

The air port 150 is installed to close the open upper end of the body housing 110, and a plurality of inlets 151 are formed through the air port 150 along the circumference. The inlet ports 151 are formed so as to communicate with the interior of the respective compression chambers 141 and are selectively opened and closed by respective opening and closing valves 152.

At this time, the on-off valve 152 is installed to block the inlet 151 in the space in the compression chamber 141 and is separated from the inlet 151 by the expansion force when the compression chamber 141 expands, And is operated to communicate the compression chamber 141 with the suction chamber 161.

In addition, a discharge chamber 153 is recessed at the center of the bottom of the air port 150. At this time, a communication groove 154 is formed in the inner circumferential surface of the discharge chamber 153 so as to communicate with the inside of each compression chamber 141 of the diaphragm 140.

That is, the air in the compression chamber 141 can be discharged to the discharge chamber 153 through the communication groove 154 when the compression chambers 141 are compressed. At this time, a communication hole 155 for communicating the discharge chamber 153 with the upper space is formed on the upper surface of the discharge chamber 153, and the discharge chamber 153 is connected to the discharge chamber 153 through the communication hole 155 The air can be discharged through the air discharge pipe 163 of the cover member 160 to be described later.

Meanwhile, in the embodiment of the present invention, the diaphragm 140 is further provided with an opening-closing membrane 143 at the center side of the upper surface.

The opening closure 143 selectively opens and closes the communication groove 154 and the discharge chamber 153 of the air port 150. When the air is introduced into the compression chamber 141 through the communication groove 154, The communication groove 154 and the discharge chamber 153 are communicated with each other and the discharge chamber 153 is formed to have a plurality of incisions along the circumferential direction so as to surround the inner peripheral surface of the discharge chamber 153.

Next, the cover 160 forms a suction chamber 161 in cooperation with the air port 150.

The cover 160 is formed so as to cover the upper end of the air port 150 and is formed so as to be recessed so that a suction chamber 161 is formed between the air port 150 and the opposed surfaces. .

An air inlet pipe 162 communicating with the suction chamber 161 is formed on the upper surface of the cover 160 and a discharge chamber 153 and a communication hole 155 of the air port 150 are formed An air discharge pipe 163 communicating with the air discharge pipe 163 is protruded.

The backflow prevention member 170 is configured to prevent backflow of water through the air discharge pipe 163. The backflow prevention member 170 prevents the backflow of water through the air discharge pipe 163 between the air port 150 and the cover 160. [ And is provided on the air inlet side.

In order to prevent backflow of water, a connection hose 34 for connecting the air discharge pipe 163 with a water supply valve 31 (see FIG. 2) Is omitted, or a structure similar to that of the opening closure 143 in the discharge chamber 153 is provided.

However, the additional mounting structure of the backflow prevention side is such that water remaining between the backflow preventing side of the connecting hose 34 and the air discharge pipe 163 is still backflowed despite the closing of the backflow prevention side, And the structure of the opening and closing membrane 143 is not limited to the structure of the operation of the air pump 143, as described in the above-described prior art, There is a possibility that the backflow of water may occur due to the existence of a certain delay time from the state where the opening is made to the state where the opening is completely closed.

Therefore, in order to prevent the above-described conventional problems, in the embodiment of the present invention, the backflow prevention member 170 is installed on the air inflow side of the air discharge pipe 163, And the flow path is opened and closed by a resilient structure, so that a quick response can be obtained.

The backflow preventing member 170 is made of a rubber material and has a fixed end 171 coupled to the air port 150 as shown in FIGS. 3 to 6, The upper end of the air port 150 is extended upwardly by the discharge pressure of the air discharged to the communication hole 155 of the air port 150 or includes a resilient opening / closing end 172 which maintains a state of being clogged by the self- .

At this time, the elasticity open / close end 172 constituting the backflow preventing member 170 has a structure in which the upper end of the elastic force closing end 172 comes into contact with each other while being axially extended toward the upper part, thereby enabling quick response to opening and closing.

In addition, in the embodiment of the present invention, the fixed end 171 of the backflow preventing member 170 is formed in a stepped structure having an outer circumferential surface expanded compared to the elastic force closing end 172, A press-in jaw 156 press-fitted into the fixed end 171 of the backflow prevention member 170 and a support jaw 157 on which the bottom surface of the fixed end 171 is placed are provided around the communication hole 155, And a contact jaw 164 is formed on the bottom surface of the cover body 160 so that the upper surface of the fixing jaw 157 is in contact with the upper surface of the fixed end 171 constituting the backflow preventing member 170 It is characterized by being formed as a multi-tiered recess.

The above-described structure prevents the backflow prevention member 170 from being separated by the discharge pressure of air by keeping the backflow prevention member 170 fixed at the correct position at all times, and also prevents the backflow prevention member 170 So that a simple assembling work can be performed.

That is, considering that the air port 150 and the cover member 160 are fixed to each other by fusion bonding, the fixed end 171 of the backflow preventing member 170 is press- Since the cover body 160 is covered with the cover body 160 in a state in which it is installed in a state of being installed in a state of being installed in a state in which the backflow prevention member 170 is installed,

Hereinafter, the operation of the air pump 100 according to the embodiment of the present invention will be described in more detail.

First, when power is supplied to the air pump 100 according to the user's need, the driving motor 20 is driven and the shaft 21 of the driving motor 20 is rotated.

Thus, the inclined fin 23 eccentrically joined to the shaft 21 by the eccentric shaft 22 revolves the center of the shaft 21 in an inclined state, The circumferential surface of the rolling plate 130 to which the inclined fin 23 is coupled is repeatedly oscillated upward and downward and the diaphragm 140 coupled to the upper surface of the rolling plate 130 by the oscillation of the rolling plate 130 Are compressed and expanded repeatedly.

When the compression chamber 141 of the diaphragm 140 is expanded during the above process, the opening / closing valve 152, which closes the inlet port 151 of the air port 150, is opened, The air present in the suction chamber 161 between the compression chambers 160 flows into the compression chamber 141. At this time, the space between the discharge chamber 153 and the communication groove 154 is kept closed by the opening / closing membrane 143 of the diaphragm 140, so that air flows backward from the discharge chamber 153 into the compression chamber 141 And the elastic force closing end 172 of the backflow preventing member 170 provided on the air inflow side of the air discharge pipe 163 is in a state of being clogged by the self-restoring force as shown in FIGS. 5 and 6 The air or water from the air discharge pipe 163 to the discharge chamber 153 is prevented from flowing backward.

On the other hand, when the pressure chamber 141 of the diaphragm 140 is compressed, the air introduced into the compression chamber 141 is discharged into the discharge chamber 153 through the communication groove 154 of the air port 150 . The opening of the diaphragm 140 which has blocked the discharge chamber 153 is bent into the discharge chamber 153 by the discharge of the air so that the air is discharged from the communication groove 154 to the discharge chamber 153 Closing valve 152 closes the inlet port 151 of the air port 150 by the discharge of the air so that the pressure in the compression chamber 141 is reduced by closing the inlet port 151 of the air port 150. [ Is prevented from being discharged to the suction chamber (161).

The air supplied into the discharge chamber 153 flows into the backflow prevention member 170 provided between the discharge chamber 153 and the air discharge pipe 163 of the cover body 160, 7 and 8, the elastic force closing end 172 of the backflow preventing member 170 is forcibly opened and discharged to the outside through the air discharge pipe 163, and then the air discharge pipe 172 163 are guided by the connection hose 34 to be supplied to the water supply valve 31 and then discharged through the nozzle 33 together with the water supplied to the water supply valve 31.

In addition, when the compression chamber 141 of the diaphragm 140 is inflated again, the pressure of the air discharged through the discharge chamber 153 becomes extremely low, so that the elastic force of the backflow prevention member 170 The backflow of the water through the air discharge pipe 163 is prevented and the space between the discharge chamber 153 and the communication groove 154 is closed by the opening membrane 143 The backflow of water or air in the compression chamber 141 through the communication groove 154 is prevented again.

As a result, the compressed air supply to the water supply valve 31 is smoothly performed, while the air or water from the water supply valve 31 is supplied to the discharge chamber 153 and the compression chamber 141 is prevented.

Particularly, in the case of the open-closing membrane 143, since the compression chamber 141 is not instantaneously restored when the operation of the air pump 100 is stopped, the gas is slowly restored for a predetermined time, Even if the operation of the air pump 100 is stopped due to the self-restoring force of the elastic force closing end 172 of the backflow preventing member 170, the elastic force closing end 172 of the backflow preventing member 170 is immediately restored to its original state, The backflow of water or air can be completely prevented, and the initial pumping failure of the air pump 100 at the time of restarting the air pump 100 can be prevented.

20. Drive motor 21. Axis
22. Eccentric shaft 23. Lever pin
31. Water supply valve 33. Nozzle
34. Connecting hose 100. Diaphragm air pump
110. Body housing 120. Diaphragm guide
121. Receiving bulkhead 130. Rolling plate
131. Coupling hub 140. Diaphragm
141. Compression chamber 142. Coupling projection
143. Opening Closing 150. Airport
151. Inlet 152. Opening / closing valve
153. Discharge chamber 154. Communication groove
155. Communicating ball 156. Indentation chin
157. Base jaw 160. Cover base
161. Suction chamber 162. Air inlet pipe
163. Air discharge tube 164. Contact tuck
170. Reverse flow preventing member 171. Fixing end
172. Elasticity

Claims (5)

A body housing which forms an outer appearance and in which an operation space is formed;
A rolling plate disposed in the body housing and receiving a driving force of the motor to rotate in the up and down direction;
A diaphragm having a plurality of compression chambers coupled to an upper end of the rolling plate and repeating compression and expansion by up and down movement of the rolling plate;
An air port formed with a discharge chamber communicated with each compression chamber of the diaphragm and having a communication hole communicating the discharge chamber with the upper space;
A cover member having an air inlet pipe communicated with the suction chamber and an air discharge pipe communicating with the discharge chamber protruded from the upper surface, the cover member being formed on an upper surface of the cover member so as to cover the upper end of the air port; And,
And a backflow prevention member provided on an air inflow side of the air discharge pipe between the air port and the cover body to prevent backflow of water through the air discharge pipe while the flow passage is opened and closed elastically. Framed air pump. The method according to claim 1,
The backflow prevention member
A fixed end coupled to the air port,
And an elastic open / close end extending upward from the fixed end, the upper end of the diaphragm extending by the discharge pressure of air discharged through the communication hole, or maintaining a state where the upper end is disentangled by self-restoring force. Type air pump. 3. The method of claim 2,
Wherein the fixed end of the backflow prevention member is formed in a stepped structure having an expanded outer peripheral surface as compared with the elastic opening closing end,
A press-in jaw which is press-fitted into the fixed end of the backflow preventing member and a receiving jaw on which the bottom surface of the jumping end is mounted are protruded and formed around the communication hole in the upper surface of the air port,
Wherein a bottom surface of the cover body is recessed and formed with a plurality of contact tangs which are in contact with the upper surface of the base of the base and the upper surface of the fixed end of the backflow preventing member. The method according to claim 2 or 3,
Wherein the elasticity closing end of the backflow preventing member is formed to have a structure in which the upper ends thereof are in contact with each other while being axially moved toward the upper part. 3. The method of claim 2,
A communication groove is formed in the inner circumferential surface of the discharge chamber of the air port so as to communicate with the inside of the compression chamber of the diaphragm,
Wherein the diaphragm is provided with a plurality of openings along the circumferential direction at a central portion of the diaphragm so as to surround the inner circumferential surface of the discharge chamber so that the communication groove communicates with the discharge chamber when air flows through the communication groove, Wherein the diaphragm-type air pump further comprises a diaphragm-type air pump.

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