KR200303353Y1 - Bubble forming device using electric - Google Patents

Abstract

The present invention relates to a bubble generator for supplying air into water such as an aquarium, and more particularly, to provide an electric bubble generator that can efficiently absorb vibrations and noises generated from a diaphragm and reduce parts and assembly labor. have.

Accordingly, in the present invention, in the electric bubble generator in which a plurality of dampers are installed in the frame to absorb a vibration generated from the diaphragm, the one frame supporting the iron core and the like having a coil wound around the body, the frame Are respectively installed to be joined to both sides of the iron core so that the iron cores are installed together, and damper coupling plates are formed so that the dampers are installed at wider intervals, and the dampers are installed at wider intervals.

Therefore, the present invention absorbs vibration efficiently while supporting the iron core more firmly, thereby preventing the loss of air supply and cooling the heat generated from the coil and the iron core more efficiently, thereby improving product quality and reliability. In addition, it is possible to produce a frame using a thin steel plate, and there is a useful effect of greatly reducing the production cost by reducing the number of parts and assembly such as a plurality of screws and washers.

Description

Bubble forming device using electric}

The present invention relates to a bubble generator for supplying air into water such as an aquarium or a septic tank, and more particularly, an electric bubble generator for supplying air by vibrating pumping a diaphragm by vibration of an electrically operated vibrating body. It is about.

In general, the aquarium is installed in the home, office, or other places to decorate the atmosphere colorfully and vividly, and is widely used because of the vitality of fish swimming and playing, and the natural friendliness of various seaweeds and gravel. .

In such an aquarium, a separate bubble generator is installed to maintain the life of the fish. The bubble generator continuously supplies air into the water to provide oxygen for the life of the fish.

In addition, a bubble generator is also installed in the case of a septic tank that has become popular recently. The bubble generator installed in such a septic tank continuously provides a lot of bubbles in the water to activate microorganisms, thereby quickly decomposing pollutants and suspended solids, thereby playing an important role in purifying sewage.

Most of these bubble generators are operated by electricity, and FIG. 1 illustrates an example of a conventional bubble generator, and focuses on a frame 30 supporting components such as an iron core 20. The upper surface of the body 11 is installed in a structure in which a substantially '∪' shaped frame 30 is supported by four dampers 50.

Vibrating body accommodating holes 30a are formed in the outer both sides of the frame 30, respectively, and outer case 25 having the diaphragm 23 and the like is fastened to the vibrating body accommodating holes 30a. . In addition, two iron cores 20 having the coil 21 wound around the frame 30 are installed at predetermined intervals, respectively. And each iron core 20 is fixed to the inner bottom surface and both sides of the frame 30 by fastening the screws (S) for a firm fixing.

In detail, each iron core 20 in which thin iron plates are stacked is not shown, but holes are drilled in four places to which the screws S are fastened, and screws S and washers W are inserted into the respective holes to support the iron cores. It is coupled with the rod 31, thereby the damper 50 is to support the frame 30 at a narrower interval than the iron core supporting rod (31).

The iron core support rod 31 is screwed to the inner bottom surface of the frame 30, the iron core fixing plate 32 is additionally installed on the front side and the rear side upper surface of the iron core 20, such The iron core fixing bracket 32 has an upper surface fastened to the front side and the rear side upper surface of the iron core 20 by screws S and washers W, and both sides of both sides of the frame 30 by screws S. Is fastened to.

The operation principle of the conventional bubble generator 10 configured as described above will be briefly described with reference to FIGS. 1 and 2, and the vibrating body 22 positioned between the two coils 21 is applied to the generated magnetic field of the coil 21. It is repeatedly conveyed from side to side along the vibrating body feed shaft 24. As a result, the vibration pushers 22a provided on both sides of the vibration body 22 vibrate the diaphragm 23 repeatedly, and the diaphragm 23 vibrates and pumps together with the vibration pusher 22a.

Therefore, the check valve plate 22b blocking the plurality of exhaust holes 22c is repeatedly opened and closed by the pumping of the diaphragm 23, thereby supplying air to the exhaust hose 26 side.

On the other hand, the air supply principle of the bubble generator 10 in more detail for this is described in detail in the patent application No. 2002-1612 previously filed.

Accordingly, the bubble generator 10 inevitably generates severe vibrations by the left and right transport of the vibrating body 22 and the diaphragm 23, and this vibration causes the frame 30 on which the coil 21 and the iron core 20 are installed. It is vibrated severely. Therefore, in the related art, the above-described four dampers 50 prevent the vibration from being transmitted to the body 11 and support the frame 30.

However, since the damper 50 has to be installed in the frame 30 at a narrow interval r due to the iron core support rod 31, the conventional bubble generator 10 cannot support the frame 30 more stably. Several problems have occurred.

That is, the damper 50 should be installed at a wide interval r in the frame 30 to absorb more effective vibration. However, in the conventional bubble generator 10, as shown in FIG. 1, the installation of the damper 50 is inevitably limited due to the iron core support rod 31, and thus, the damper 50 is installed at a narrow interval r. Therefore, the vibration of the frame 30 is intensified, and thus the frame 30 cannot be supported more stably and firmly.

In addition, since the frame 30 applied to the conventional bubble generator 10 has a '∪' shape, installation of the damper 50 may be limited. That is, in order to install the dampers 50 at wide intervals, the bottom surface of the frame 30 should be widened. If the shape of the frame 30 is changed, other sizes such as the iron core 20 and the vibrating body 22 of the standardized size are different. The size and shape of the parts can not but be changed. Therefore, since excessive production costs are required, the bottom surface of the frame 30 may not be extended in a realistic manner.

As described above, although the damper 50 is installed in the conventional bubble generator 10, the vibration of the frame 30 was not properly absorbed, and thus, the vibration of the frame 30 is transmitted to the body, and thus the bubble generator as a whole. (10) vibrated violently, and the vibration accompanied noise, which further lowered the reliability of the product.

Furthermore, since the vibration affects the vibration of the diaphragm 23, it acted as a barrier to the stable vibration of the diaphragm 23, and as a result, the air supplied by the diaphragm 23 is lost, thereby reducing the performance of the product. A problem has occurred. In addition, the diaphragm 23 is easily broken due to the external vibration continuously acting, which causes frequent problems such as frequent replacement or new purchase.

In addition, since the frame 30 applied to the conventional bubble generator 10 has a structure covering the bottom and both sides of the iron core 20 due to the characteristics of the shape, a lot of heat generated from the coil 21 and the iron core 20 is easy. The problem of shortening the life of the coil 21 has not occurred due to the cooling.

In addition, the conventional bubble generator 10 forms a hole in about 10 places of the iron core 20 to fix the iron core 20 to the frame 30, the screw (S) and the washer (W) and the iron core fixing plate (32) is used to fasten with the iron core support rod (31).

Therefore, the drilling work for forming a hole in the iron core 20 and a plurality of screws (S), washers (W), iron core support rods 31 and the iron core fixing plate 32 is required, so the number of parts and assembly labor is increased. As a result, the manufacturing cost of the bubble generator is greatly increased, thereby weakening the price competition of the product.

In addition, the assembly structure using the screw (S), washer (W), iron core support rod 31, and iron core fixing plate 32 has been an important cause of noise generation because the contact portion of the metal portion is increased. As a result, considerable noise is generated together with the vibration of the frame 30, which further lowers the productability and reliability of the product.

The present invention is devised to solve the conventional problems as described above, the object of the present invention is to install the frame integrally to the iron core so that the dampers can be installed at a wider interval and the vibration generated by the diaphragm It is to provide an electric bubble generator that can absorb the noise more efficiently.

In addition, another object of the present invention is to provide an electric bubble generator that can install the frame integrally to the iron core to reduce the number of parts and assembly labor such as screws and washers to reduce the production cost of the product and improve productivity.

Another object of the present invention is to provide an electric bubble generator that can prevent the supply loss of air because the diaphragm is normally vibrated by the vibration absorption of the dampers installed at a wider interval.

1 is a perspective view showing an electric bubble generator without a lid according to the prior art,

FIG. 2 is an enlarged plan sectional view of a portion of an outer case showing an operation relationship of a bubble generator for bubble generation in FIG. 1; FIG.

Figure 3 is a perspective view of the electric bubble generator without the lid according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10 bubble generator 11 body

20: iron core 21: coil

22: vibrating body 22a: vibration pusher

23: diaphragm 24: vibrating feed shaft

25: outer case 26: exhaust hose

40: frame 40a: vibrating body receiving hole

41: core joint 42: damper coupling plate

50: damper R, r: spacing

The electric bubble generator of the present invention for achieving the above object is provided with a plurality of dampers are installed on the frame to absorb a vibration generated from the diaphragm is installed on the upper surface of the body is a single frame for supporting the iron core having a coil wound In the electric bubble generator, the frames are respectively installed are bonded to both sides of the iron core so that the installation of the iron core together, and the damper coupling plate is formed so that the dampers are installed at a wider interval.

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

As shown in FIG. 3, the present invention is provided with frames 40 coupled to the dampers 50 at left and right sides of the upper surface of the body 11, and each of the frames 40 has iron core joint portions 41 at both sides thereof. It is bent in the direction of (20) and joined to both side center portions of the iron core 20 provided between the frames 40 by welding or the like.

Due to this, the iron core 20 made of a plurality of iron plate is installed together with only the welding operation with the iron core joint portion 41 of the above-described frame 40 without a separate assembly work.

Each frame 40 is provided with a vibrating body accommodating hole 40a, and an outer case 25 having a diaphragm 23 and an exhaust hose 26 is provided outside the vibrating body accommodating hole 40a. .

In addition, a damper coupling plate 42 to which the damper 50 is coupled is bent under each frame 40. Since the damper coupling plate 42 is bent in a direction opposite to the direction in which the frames 40 face each other, the dampers 50 coupled to the respective damper coupling plates 42 are frame 40 at a wide interval (R). It is supported firmly and stably.

Referring to the operation and effects of the present invention configured as described above in detail.

As shown in FIG. 3, in the bubble generator 10 of the present invention, the vibrating bodies 22 positioned between the coils 21 on both sides are repeatedly conveyed from side to side along the vibrating body feed shaft 24 by a change in the magnetic field. Accordingly, the vibration pushers 22a formed on both sides of the vibrator 22 repeatedly vibrate the diaphragm 23 provided inside the outer case 25, and thus the diaphragm 23 vibrates and pumps the exhaust hose 26. ) To supply air to the side. The air supply process of the bubble generator 10 in more detail is the same as the conventional description with reference to FIG.

The vibration generated in this process is transmitted to the frame 40 and the iron core 20, etc., the plurality of dampers 50 coupled to the damper coupling plate 42 of the frame 40 is coupled to the damper of a shorter interval (R) The plate 42 causes the vibration generated from the diaphragm 23 to be more effectively absorbed.

That is, the damper coupling plate 42 formed below each frame 40 is bent in the opposite direction to the direction in which the frame 40 faces each other, so that the gap between the damper coupling plates 42 becomes very wide. Accordingly, the present invention supports the heavy core iron core 20 more stably and firmly, and absorbs vibrations more efficiently by the plurality of dampers 50 installed in the damper coupling plate 42.

In particular, efficient vibration absorption is very important in terms of efficient air supply. The reason is that in the case of the diaphragm 23 which vibrates about 60 times a minute, stable and constant vibration pumping is performed only when the generated vibration is sufficiently dissipated. For losing. If the vibration is not sufficiently dissipated, the residual vibration affects the vibration of the diaphragm 23, the diaphragm 23 is not able to vibrate constantly, and this causes a loss of air supply.

Therefore, since the frame 40 of the present invention is directly bonded to the iron core 20 and the damper 50 is installed in a wider structure, the frame 40 efficiently absorbs vibration generated from the diaphragm 23 to prevent loss of air supply. Done.

Furthermore, the frame 40 of the present invention has a structure in which the iron core joint portion 41 formed at both sides is directly bonded to the iron core 20 by welding, so that the frame 40 and the iron core 20 are more firmly coupled. do. Therefore, it is possible to produce the frame 40 by using a thinner thickness of the steel plate, and can greatly reduce the overall size of the frame 40, thereby greatly reducing the material cost for producing the frame 40.

And in the past, as shown in Figure 1 in order to install the iron core 20, the screw (S), washer (W), iron core support rod 31, and iron core fixing plate 32 was used, but in the present invention Such a component is unnecessary, and a drilling operation for forming a hole in the iron core 20 as in the prior art is also unnecessary. Therefore, this greatly reduces the production process of the iron core (20).

In addition, since the frame 40 of the present invention is integrally bonded to the iron core 20, a plurality of iron plates constituting the iron core 20 are firmly fixed so that a minute vibration does not occur. In the conventional method of assembling the frame 30 and the iron core 20 using components such as S) and the washer (W), there must be a minute gap between the components, and as a result, the screw S is tightened as time passes. Is bound to loosen.

However, the present invention for integrally joining the frame 40 and the iron core 20 by welding is to reduce the vibration and noise further because the minute gap does not occur due to the characteristics of the welding method such as welding.

And the frame 40 of the present invention is simply a structure directly bonded to the central portion of both sides of the core 20, the cooling efficiency of the iron core 20 and the coiled coil 21 is increased. That is, since it is not a shape surrounding the iron core 20 as in the related art, the heat discharged from the wound coil 21 and the iron core 20 is more efficiently cooled, thereby extending the life of the bubble generator 10.

On the other hand, the above-described embodiment is merely to explain an example of a preferred embodiment of the present invention, the scope of the present invention is appropriately changeable within the scope of the same idea limited to such.

As described above, the present invention is installed on the upper surface of the body at wider intervals, so that the iron core of heavy load is more firmly supported, and the vibration is efficiently absorbed to prevent loss of air supply. The height is effective.

In addition, the present invention is capable of producing a frame using a thin steel plate due to the nature of the method in which both sides of each frame is directly bonded to both sides of the iron core, and the size of the frame is smaller than the conventional frame, so the material cost associated with the frame It is effective to reduce.

In addition, since a number of screws, washers, and iron core rods are unnecessary, the number of parts and the number of assembly operations can be greatly reduced, thereby producing a cost-effective product.

In addition, in the present invention, since both sides of the frame are directly bonded to both sides of the iron core, there is no gap between the frame and the iron core and a plurality of iron plates forming the iron core. Therefore, a fine vibration does not occur due to the nature of the bonding method, thereby further reducing the vibration and noise.

In addition, since the frame is a structure in which the frame is directly bonded only to the center portion of both sides of the iron core without surrounding the iron core as in the related art, many parts such as the wound coil and the bottom of the iron core are exposed to the outside. Therefore, there is also a very useful effect of cooling the heat generated from the wound coil and the iron core more efficiently and extend the life of the bubble generator.

Claims (2)

In the electric bubble generator in which a plurality of dampers are installed in the frame so that a single frame for supporting an iron core having a wound coil is installed on the upper surface of the body to absorb vibration generated from the diaphragm, The frames 40 are respectively installed and bonded to both side surfaces of the iron core 20 so that the installation of the iron core 20 is performed together, and the damper coupling plates so that the dampers 50 are installed at a wider interval R. 42) electric bubble generator characterized in that it is formed. The method according to claim 1, wherein each of the frames 40 and the iron core joint portion 41 formed on the left and right to be integrally bonded with the iron core 20; Damper coupling plate 42 is formed in the lower portion of each frame 40 in the opposite direction facing each other so that the dampers 50 are installed at a wider interval (R) Electric bubble generator comprising a.