KR20030021126A - A device for converting air path and an air pump - Google Patents

Abstract

PURPOSE: An apparatus for converting channel of air and an air pump are provided to secure sealing by a valve body. CONSTITUTION: Three branching chambers(15,16,17) are fluidically communicated by communicating holes(14a) formed on a pair of partitions(14) facing each other, and forming the branching chambers. A valve body(21) is placed in the middle branching chamber with an air inlet(22a). The valve body converts opening and closing of the communicating holes to convert communication between the air inlet of the middle branching chamber and air outlets of the other branching chambers. The valve body is a perfectly round sphere.

Description

Air flow diversion device and air pump {A DEVICE FOR CONVERTING AIR PATH AND AN AIR PUMP}

The present invention relates to an air flow path switching device and an air pump having the air flow path switching device.

There is known an air pump in which an air flow path switching device is combined with one air pump to switch the air supply source (see Japanese Patent Laid-Open Nos. 10-238473 and 2000-274372).

The structure of the air flow channel switching device incorporated in the air pump of these publications is as shown in FIG.

In Fig. 5, reference numeral a denotes an air flow path switching device, and the air flow path switching device (a) divides the inside of the noise chamber (b) formed below the air pump main body (not shown) into the partition wall c and Three branch chambers (e, f, g) formed by partitioning into a pair of opposing partitions (d) are provided. The pair of partitions d are formed with communication holes h for communicating the three branching chambers e, f, and g, respectively, and these communication holes h have a ring-shaped sealing material made of elastic rubber. (i) is mounted. Of the three branching chambers e, f and g, a cylinder k having an air inlet j is arranged in the central branching chamber f so as to connect the two sealing materials i. In the cylinder k, a rod 1 whose one end is connected to a solenoid (not shown) constituting the solenoid switching valve is inserted, and a short cylindrical valve body m It is fixed integrally so that it may be arrange | positioned in the said center branch chamber f. The cylindrical portion n protrudes toward the noise chamber b in the central branch chamber f, and the inside of the cylindrical portion n is the air inlet o. Although not shown in the other two branch chambers e and g, the cylindrical part which has an air outlet port protrudes out of the tank.

Then, the excitation of the solenoid and the element are alternately switched to move the valve body m to switch the opening and closing of the two communication holes h so as to switch between the air inlet o and the two air outlets. Doing.

By the way, in the air flow path switching device (a) as described above, the dust contained in the air flowing from the air inlet (o) enters a slight gap between the cylinder (k) and the valve body (m), the valve body (m) It may interfere with the operation of. However, if the cylinder k is not present, the problem of intrusion of dust will be solved, but the careful action caused by the cylinder k will be eliminated, and the valve body m will be displaced in the radial direction. ), The contact hole h becomes insufficient, so that the communication hole h cannot be reliably sealed.

In addition, when the inflowing air comes into contact with the corner of the cylindrical valve element m or the periphery of the air inlet j of the cylinder k, fluid sound is generated and pressure loss is caused. do.

This invention is made | formed in view of such a problem, and the objective is to ensure the operation | movement of a valve body and sealing by a valve body, and to solve a fluid sound and a pressure loss.

FIG. 1A is an enlarged view of the air flow channel switching device according to the first embodiment, and FIG.

2 is a configuration diagram of an air pump to which an air flow channel switching device according to a first embodiment is applied;

3 is a plan view of a noise chamber of an air pump to which an air flow channel switching device according to a first embodiment is applied;

4A is an enlarged view of the air flow channel switching device according to the second embodiment, and FIG. 4B is a view for explaining the careful action thereof.

Figure 5 (a) is an enlarged view of a conventional air flow path switching device, (b) is a view of a state of switching the air flow path

Explanation of symbols on the main parts of the drawings

5-Mounting Plate 8-Air Pump Body

14-bulkhead 14a-communication hole

15,16,17-Branch chamber 21-Valve body

21a-tapered surface 22a-Air inlet

23a, 24a-Air outlet 25-Air flow path switching device

In order to achieve the above object, the present invention is characterized by devising the shape of the valve body.

Specifically, in the present invention, three branch chambers are formed by a pair of opposing partitions. Among the branch chambers, an air inlet is formed in the center branch chamber, and an air outlet is formed in the other two branch chambers, respectively. And a communication hole communicating with the three branch chambers is formed in each of the pair of partition walls, a valve body is disposed in the central branch chamber so as to open and close the communication hole, and the valve body opens and closes the two communication holes. As the air flow path switching device in which the air inlet port and the two air outlet ports are switched in connection with each other, the following solutions have been devised.

That is, the invention described in claim 1 is characterized in that the valve body is a sphere.

In the invention described in claim 2, the contact portion of the valve body in contact with the peripheral portion of the communication hole is formed in a tapered surface.

According to the above structure, even if the position of the valve body is shifted in the radial direction, the valve body is a sphere in claim 1, and in the second embodiment, the contact portion of the valve body in contact with the periphery of the communication hole is formed as a tapered surface. As a result, a slide is generated in the valve body at the contact portion with the peripheral edge of the communication hole, and the valve body is returned to the normal position. By this careful action, the communication hole is reliably sealed by the valve body.

In addition, since the cylinder as in the conventional example is not required, the operation of the valve body due to the intrusion of dust is eliminated and the manufacturing cost is reduced by that.

In addition, since there is no corner at the valve body and there is no cylinder as in the prior art, the inflowing air flows smoothly, and no fluid sound comes into contact with the peripheral constituent members, and there is no pressure loss.

The invention according to claim 3 includes an air pump main body and a noise chamber, wherein the air flow path switching device according to claim 1 or 2 is provided adjacent to the noise chamber.

According to the above configuration, an air pump having an air flow path switching device having the above-described characteristics can be obtained.

Embodiment of the Invention

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an air flow path switching device according to a first embodiment of the present invention, and Figs. 2 and 3 are views showing an air pump to which the air flow path switching device is applied. In this embodiment, although the electromagnetic vibration type diaphragm type | mold air pump used for a sewage purification tank is illustrated as an air pump, it is not limited to this.

In Fig. 2, reference numeral 1 denotes a casing composed of an upper casing 2 and a lower casing 3, and four leg portions on the back side of the lower casing 3 are ground leg portions made of elastic rubber ( 4) are attached respectively. The upper casing 2 and the lower casing 3 are partitioned up and down by an attachment plate 5, and the inside of the upper casing 2 is the pump storage chamber 6 and the inside of the lower casing 3 is noisy. Each of the threads 7 is configured.

In the pump storage chamber 6, the air pump main body 8 is arranged to be supported by the attachment plate 5 by a shock absorbing member 9 made of dustproof rubber or the like. Although not shown, the air pump body 8 includes an electromagnet and a permanent magnet fixed to the drive shaft. On both sides of the air pump body 8, a compression chamber 10 having a diaphragm (not shown) is formed, and the diaphragm is connected to the drive shaft. Both compression chambers 10 communicate with the silencer 7 by rubber hoses 11, respectively.

Meanwhile, in order to prevent pulsation and noise caused by air introduced from the air pump main body 8, three plates 12 are provided in the silencer 7 so as to bypass the air passages. Next, three branching chambers 15, 16, and 17 are partitioned by partition walls 13 and a pair of partition walls 14 facing each other.

As enlarged in FIG. 1, the pair of partitions 14 are formed with circular communication holes 14a communicating with the three branching chambers 15, 16, and 17, respectively. A ring-shaped sealing material 18 made of elastic rubber is attached to 14a), and a valve seat 18a is formed on the central branch chamber 16 side of the sealing material 18. As shown in FIG.

Of the three branch chambers 15, 16 and 17, a solenoid 19 constituting an electromagnetic switching valve is disposed in the branch chamber 17 located at the lower side (right side in FIG. 1) in FIG. The rod 20 is integrally connected to the solenoid 19 so as to pass through the two communication holes 14a.

As a feature of the present invention, a valve body 21 made of a spherical sphere is fixed to the middle of the rod 20 so as to be disposed in the central branch chamber 16.

A cylindrical portion 22 protrudes toward the noise chamber 7 side in the central branch chamber 16, and the inside of the cylindrical portion 22 is an air inlet 22a. In the other two branching chambers 15 and 17, cylindrical portions 23 and 24 having air outlet ports 23a and 24a are formed to protrude out of the tank (lower casing 3), respectively. The air outlet 23a on one side of the two air outlets 23a and 24a is connected to an aeration pipe provided at the bottom of the aerobic filter bed of the septic tank. The other air outlet 24a is connected to an air diffuser for backwashing an aerobic filter.

The diaphragm vibrates in the compression chamber 10 by reciprocating the drive shaft by changing the magnetic polarity of the suction or repulsion of the electromagnet according to the power source frequency with respect to the magnetic force generated in the permanent magnet, whereby the air vibrates in the compression chamber 10. 10) are sucked and compressed, and are introduced into the noise chamber (7) through the rubber hose (11). The air introduced into the silencer 7 flows into the central branch chamber 16 from the air inlet 22a, alternately switches the excitation of the solenoid 19 and the element to the valve body 21 in FIG. And the air inlet 22a and the two air outlets 23a and 24a are switched by connecting the opening and closing of the two communication holes 14a by moving as shown by the solid line, whereby the air pump main body 8 The discharged air is supplied from the air outlet 23a to the aeration diffuser of the sewage treatment tank or from the air outlet 24a to the backwashing diffuser so as to purify the sewage and clean the aerobic phase.

Therefore, the air flow path switching device 25 is constituted by the three branch chambers 15, 16, 17, the solenoid 19, the valve body 21, the air inlet 22a, and the air outlet 23a, 24a. do.

In addition, the air flow path switching device 25 is alternately switched to operate according to the command of the control device 26 (see Fig. 2).

Thus, in this embodiment, since the valve body 21 is comprised concretely, as shown by the virtual line in FIG. 1 (b), the valve body 21 is shifted in the radial direction, and the sealing material 18 Even if the valve seat 18a is not seated on the valve seat 18a, a slide of the valve body 21 occurs at the contact portion with the sealing material 18, which is the periphery of the communication hole 14a, and the valve body 21 returns to the normal position. By this careful action, the communication hole 14a can be reliably sealed by the valve body 21.

In addition, in this embodiment, since the cylinder k like the conventional example (refer FIG. 5) is unnecessary, the malfunction of the valve body 21 by the invasion of dust is eliminated, and the manufacturing cost can be reduced by that much. Can be.

In addition, in this embodiment, since the valve body 21 does not have a corner part and there is no cylinder k as in the prior art, the inflowing air flows smoothly and eliminates the generation of the fluid sound by contact with the peripheral constituent members. It can eliminate the pressure loss by this.

4 shows a second embodiment of the air flow channel switching device 25. In this second embodiment, the valve body 21 is shaped like a main plate egg, and the contact portion of the valve body 21 that contacts the peripheral portion of the communication hole 14a, that is, the sealing material 18 is linear. It is formed by the tapered surface 21a of the upper surface. Otherwise, since it is the same structure as 1st Embodiment shown in FIG. 1, the same code | symbol is attached | subjected to the same component part, and the detailed description is abbreviate | omitted.

Therefore, in 2nd Embodiment, the effect similar to 1st Embodiment mentioned above can be achieved.

In addition, the shape of the valve body 21 is not limited to the above two examples, For example, an egg-shaped sphere may be sufficient, and the taper surface 21a of the valve body 21 of 2nd Embodiment is curved in convex shape. The tapered surface or the tapered surface curved in a concave shape may be formed.

As described above, according to the present invention, the valve body is constituted by a sphere, or the contact portion in contact with the periphery of the communication hole in the valve body is formed in a tapered surface, so that the valve body is displaced in the radial direction. Even if it is, the communication hole can be reliably sealed by returning the valve element to the normal position by the slide on the contact surface. In addition, since the cylinder as in the conventional example is not required, the malfunction of the valve body due to the intrusion of dust can be eliminated, and the manufacturing cost can be reduced by that amount. In addition, it is possible to eliminate the generation of fluid sound and the loss of pressure due to the corner portion of the valve element or the presence of a cylinder as in the conventional example.

Claims (3)

Three branch chambers are formed by opposing pairs of partitions, In the branch chamber, an air inlet is formed in the central branch chamber, and an air outlet is formed in the other two branch chambers, The pair of partition walls are each formed with a communication hole for communicating the three branch chambers, The valve body is arranged in the central branch chamber so as to open and close the communication hole, An air flow channel switching device in which the valve body switches the air inlets and the two air outlets by switching the opening and closing of the two communication holes. Air flow path switching device characterized in that the valve body is a sphere. Three branch chambers are formed by opposing pairs of partitions, In the branch chamber, an air inlet is formed in the central branch chamber, and an air outlet is formed in the other two branch chambers, The pair of partition walls are each formed with a communication hole for communicating the three branch chambers, The valve body is arranged in the central branch chamber so as to open and close the communication hole, An air flow channel switching device in which the valve body switches the air inlets and the two air outlets by switching the opening and closing of the two communication holes. The air flow path switching device, characterized in that the contact portion of the valve body in contact with the peripheral portion of the communication hole is formed with a tapered surface. Equipped with air pump body and noise chamber, The air pump according to claim 1 or 2, wherein the air flow path switching device is installed adjacent to the silencer.