KR20010050516A - Aeration system - Google Patents

Abstract

PURPOSE: To attain the miniaturization and cost reduction of a water immersion detecting mechanism for detecting the water immersion into a motor chamber 40. CONSTITUTION: An immersion water storage chamber 70 separated from a motor chamber 40 is formed at the bottom part of the motor chamber 40. The immersion water storage chamber 70 is provided with an electrode type liquid level sensor 80. The signal line 87 of the liquid level sensor 80 passes through a space between the stator 2a of a motor 2 and a stator casing 1b and is connected with an adaptor 75 of a motor cover 1a. A cab tire cable 76 for housing the signal line 87 of the liquid level sensor 80 and a motor cable is led to the outside of the adaptor 75.

Description

Aeration System {AERATION SYSTEM}

The present invention relates to an aeration device used for purification of sewage.

As disclosed in Japanese Unexamined Patent Publication No. 59-228996, an axial flow vane connected to a motor shaft of an underwater motor is accommodated in an apparatus casing, and the wastewater is discharged by rotation of the axial vane. The aeration apparatus which draws to-be-processed liquid into the flow path, supplies air to the to-be-processed liquid, and performs aeration is known.

In general, in this type of aeration device, an oil seal is provided between the motor casing and the vane which define the motor compartment. However, when the to-be-processed liquid submerges in this oil chamber, lubrication performance will fall and reliability of an apparatus will fall. Therefore, in the apparatus disclosed in Japanese Utility Model Publication No. 56-48951 or Japanese Utility Model Publication No. 57-43115, an infiltration detector was installed in the oil chamber to prevent the oil chamber from being flooded. For example, Japanese Utility Model Publication No. 57-12236 discloses an inundation detector which detects inundation by detecting a change in conductivity of oil in an oil chamber.

In addition, when the liquid to be treated is infiltrated into the motor chamber, the insulation of the motor is lowered, which leads to a risk of electric leakage, and at the same time, the reliability of the device. Therefore, in the aeration apparatus disclosed in Japanese Patent Application Laid-Open No. 59-228996, a float switch was installed in the motor compartment, and flooding was detected in accordance with the ON / OFF state of the plot switch.

However, the plot of the plot switch contains a permanent magnet for operating the limit switch, and it is necessary to increase the volume of the plot in order to obtain sufficient buoyancy against the gravity of the permanent magnet. Therefore, if the large-volume plot is to be stored in the motor room, the size of the device inevitably becomes large, resulting in an increase in material cost and a deterioration in handling. When the motor is started or stopped, a relatively large magnetic field may be formed by the motor. As a result, the permanent magnet inside the plot may be lifted by the magnetic field, causing malfunction of the plot switch. In order to prevent a malfunction in this way, a method of installing the plot at a position away from the motor, or covering the plot with magnetic material is required. However, implementing such a method becomes a factor in raising the cost of the apparatus.

This invention is made | formed in view of such a point, and the objective is to provide the aeration apparatus which the reliability of motor room immersion detection is high, and its structure is small and low cost.

1 is a cross-sectional view of an aeration device according to an embodiment of the present invention.

2 is a partial cross-sectional view of a liquid level detector.

3 is a cross-sectional view of the cap tire cable.

(Explanation of symbols for the main parts of the drawing)

1: motor casing 2: motor

2a: stator 2b: rotor

3: oil casing (auxiliary casing) 4: lower shaft support (shaft support)

6: mechanical seal 8: vanes

9: suction casing 10: discharge casing

11: supply pipe 13 motor rotating shaft

16: Euro 25: oil seal

40: motor room 70: submerged storage room

76: cap tire cable 80: liquid level detector (electrode immersion detector)

81: electrode (detector) 87: signal line

In order to achieve the above object, the present invention is to detect the immersion of the motor chamber by the electrode type immersion detector.

Specifically, the first invention relates to a motor casing which defines a motor chamber for watertightly accommodating a motor, a motor rotating shaft provided on the motor so as to protrude from the motor casing, a vane fixed to the motor rotating shaft, and the vane. An aeration device comprising an apparatus casing for forming a flow path for stably mixing a liquid to be processed sucked by rotation with a predetermined gas and discharging the liquid, and an electrode type immersion detector for detecting the immersion of the motor chamber.

Thereby, when the to-be-processed liquid immerses in a motor chamber, this immersion is detected by the electrode type immersion detector, and based on this immersion detector, a protective operation | movement, such as a motor stop, can be performed. The electrode immersion detector does not require a large volume plot, so the apparatus is miniaturized. In addition, since there is little possibility of malfunction due to starting or stopping of the motor, anti-magnetic treatment is unnecessary and the cost of materials can be reduced. In addition, since there are few malfunctions, the reliability of the apparatus is improved.

According to a second aspect of the present invention, in the motor rotation shaft, a mechanical seal and a shaft support supporting the motor rotation shaft above the mechanical seal and below the motor are provided on the motor rotation shaft, and the detection unit of the electrode type immersion detector is the mechanical seal. It is to be installed above and below the shaft support.

In this way, the immersion detection is carried out below the bearing, so that the immersion is detected before the liquid to be infiltrated into the motor chamber reaches the bearing, so that a quick and effective immersion can be implemented.

In the third invention, in the first invention, the motor is provided above the van.

The submerged storage chamber partitioned from this motor chamber is provided in the bottom part of a motor chamber, and the detection part of an electrode type immersion detector shall be provided in the said submerged storage chamber.

Thereby, the to-be-processed liquid which penetrated into the motor chamber from the van by the shaft sealing part, such as a mechanical seal, once flows into a immersion storage chamber. Therefore, the liquid to be infiltrated into the motor compartment from the van does not flow directly into the motor, so that the flooding of the motor is unlikely to occur. In addition, since the immersion detection is performed in the immersion storage chamber, the detection accuracy is improved.

According to a second aspect of the present invention, in the second aspect of the present invention, the motor is provided above the vane, and an auxiliary casing is provided at the bottom of the motor chamber to accommodate the shaft support and partition the submerged storage chamber partitioned from the motor chamber. The detection part of the electrode type immersion detector is provided in the immersion storage chamber.

As a result, as in the third invention, immersion of the motor is unlikely to occur, and accuracy of immersion detection is improved. In addition, the submerged storage chamber is partitioned by the auxiliary casing, and the bearing is housed in the auxiliary casing, thereby simplifying the configuration of the apparatus and further reducing the material cost.

In a fifth aspect of the present invention, the motor has a stator fixed inside the motor casing and a rotor provided inside the stator. The signal line of the electrode type immersion detector is the motor. It is assumed that it is drawn outward from the top of the motor casing through the casing and the stator.

This eliminates the need to form a signal line guide guide in the middle of the motor casing, thereby simplifying the device configuration.

In the sixth invention, in any one of the first to fourth inventions, the signal line of the electrode type immersion detector is housed inside the cap tire cable together with the motor cable for supplying electric power to the motor.

As a result, the lead wires drawn out of the device can be constituted by a single cap tire cable, thereby simplifying the configuration of the device. In addition, there is less risk of damage to signal lines or motor cables, and the reliability of the device is further improved.

The above and other objects and features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

(Example)

Embodiments of the present invention will be described below with reference to the drawings.

As shown in FIG. 1, the aeration device 20 is a so-called submersible mechanical aeration device from above, as the vanes 8 connected to the rotating shaft 13 of the motor 2 rotate. Sewage mixed with water), and the air supplied through the air supply pipe 11 and the to-be-processed liquid are stirred and mixed and discharged from the lower discharge port 15.

Configuration of aeration device

First, the configuration of the aeration device 20 will be described. The device casing B of the aeration device 20 is configured by mounting and fixing the suction casing 9 on the discharge casing 10. The suction casing 9 is formed in a substantially cylindrical shape and spreads toward the upper opening to facilitate the suction of the liquid to be processed. Around the outer circumference of the lower opening of the suction casing 9, a flange 31 serving as a connection portion with the discharge casing 10 is provided. The upper end of the discharge casing 10 is opened concentrically with the lower opening so as to smoothly continue with the lower opening of the suction casing 9, and a flange 32 is formed around its outer circumference. The two flanges 31 and 32 abut each other. The suction casing 9 and the discharge casing 10 are fixed by the combination of these two flanges 31 and 32 and bolts (not shown). In this way, the inner surface of the device casing B is formed as a circumferential surface.

In the bottom part of the discharge casing 10, the flat part 33 provided with the insertion hole 34 for the air supply pipe 11 is formed in the center. A part of the periphery of the flat portion 33 is formed with an inclined inner surface 35 inclined downward toward the outside. The discharge port 15 is formed between the inner inclined surface 35 and the inclined outer portion similarly to the inner inclined surface 35. Thus, in the apparatus casing B, the flow path 16 of the type | mold which discharges the to-be-processed liquid sucked from the upper direction through the suction port 14 toward the substantially horizontal direction from the discharge port 15, changing a flow direction is formed. do.

The air supply pipe 11 connected to the blower (not shown) as an air supply source is connected to the flat part 33 of the discharge casing 10. The air supply pipe 11 penetrates the insertion hole 34, and the opening part protrudes upward from the bottom surface of the discharge casing 10. As shown in FIG. The opening of this air supply pipe 11 opposes the upper surface of the air chamber casing 12 which partitions the air chamber 17 and the flow path 16 at predetermined intervals. The air chamber casing 12 defines an air chamber 17. This air chamber 17 is for storing the air supplied from the air supply pipe 11 once, and then evenly supplying the flow path 16. As shown in FIG. The side surface of the air chamber casing 12 is inclined along the inclined surface 35 inside the discharge casing 10. The lower end of the air chamber casing 12 is provided with a supply path 18 for supplying air in the air chamber 17 to the liquid to be processed in the flow path 16 to be stirred and mixed. Here, the air chamber casing 12 functions as a diffuser for directing the liquid to be treated to the discharge port 15.

The upper part of the apparatus casing B is provided with the main-body part A which gives the driving force to attract and stir the to-be-processed liquid. The main body portion (A) includes a motor casing (1), a motor (2) housed in the motor casing (1), a rotating shaft (13) of the motor (2), an oil casing (3), a mechanical seal bracket (7), and An impeller 8 etc. are assembled and comprised.

The motor casing 1 is provided with the substantially cylindrical stator casing 1b and the motor cover 1a which water-tightly closes the upper part of the stator casing 1b. The motor cover 1a is provided with an adapter 75 for connecting the inner and outer conductors and watertightly holding them. The lower part of the stator casing 1b is watertightly closed by the oil casing 3, and the motor chamber 40 is partitioned inside the motor casing 1.

The motor 2 has a cylindrical stator 2a fixed to the inner wall of the stator casing 1b, and a rotor 2b arranged concentrically with the stator 2a inside the stator 2a. On the inner circumferential surface of the rotor 2b, a rotating shaft 13 extending downward is fixed. The rotary shaft 13 is supported by the upper shaft support 39 and the lower shaft support 4 so as to be free to rotate.

The oil casing 3 has a top and bottom two-layer structure, and an immersion storage chamber 70 is formed between the upper casing 71 and the lower casing 72 of the oil casing 3. That is, the submerged storage chamber 70 separated from the motor chamber 40 is formed at the bottom of the motor chamber 40. An oil chamber 25 is formed between the lower portion 72 of the oil casing 3 and the mechanical seal bracket 7.

The upper surface 71 of the oil casing 3 is provided with a liquid level detector 80 by a vis or the like. The liquid level detector 80 is provided with a plurality of electrode rods 81 as shown in FIG. 2 as electrode type liquid level detectors, and the liquid level of the submerged storage chamber 70 depends on whether each electrode rod 81 is in contact with a liquid. It is a detector to detect. The connection portion of the electrode rod 81, that is, the connection portion 85 of the electrode rod 81 and the lead wire 84, is covered with a corrosion resistant coating rubber 83. A part of this coated rubber 83 is formed in a flange shape to constitute the flange portion 86. And the lead wire 84 side part from this flange part 86 is inserted in the probe cover which is not shown in figure. Here, the material of the electrode rod 81 is preferably one excellent in corrosion resistance. For example, SUS316 or Hastelloy can be suitably used.

The rotary shaft 13 penetrates through the center of each of the upper portion 71 and the lower portion 72 of the oil casing 3. The lower shaft support 4 supporting the rotating shaft 13 is accommodated in the upper portion 71 of the oil casing 3. The lower end of the oil casing 3 outer peripheral part 21 is fixed to the outer peripheral part 22 of the mechanical seal bracket 7. On the other hand, the lower end of the inner circumference 23 of the oil casing 3 is connected to the inner circumference 24 of the mechanical seal bracket 7 via the mechanical seal 6. And the oil chamber 25 which supplies oil as a lubricant to the mechanical seal 6 which is the shaft sealing part of the rotating shaft 13 by the oil casing 3 and the mechanical seal bracket 7 is formed. As a result, the motor chamber 40, the submerged storage chamber 70, and the oil chamber 25 are formed in order from above. The electrode rod 81 which is a detection part of the liquid level detector 80 is provided above the mechanical seal 6 and below the lower bearing 4.

The motor casing 1 and the oil casing 3 are joined by bolts not shown. Therefore, the oil casing 3 supports the motor casing 1 and supports the rotation of the rotary shaft 13 freely through the lower shaft support 4.

An impeller 8 is engaged with the distal end of the rotation shaft 13. The vanes 8 are composed of a substantially cylindrical hub 36 extending in parallel with the rotation shaft 13 and a plurality of wings 37 provided to protrude from the outer circumferential surface of the hub 36. The hub 36 is provided with a rotating shaft mounting arm 36a extending toward the center thereof. The rotating shaft 13 is fitted into the mounting hole of this mounting arm 36a, and is engaged. As a result, the vanes 8 are configured to rotate in accordance with the rotation of the rotary shaft 13 to generate a suction force for leading the liquid to be processed from above to below.

On the side of the oil casing 3, a mounting arm 5 for fixing the body portion A and the device casing B is provided. The mounting arm 5 and the device casing B are joined by bolts not shown.

The signal line 87 of the liquid level detector 80 is connected to the adapter 75 through the stator casing 1b and the stator 2a. Here, a motor cable (not shown) for supplying power to the motor 2 is also connected to the adapter 75. The cap tire cable 76 is connected to the outer side of the adapter 75.

As shown in FIG. 3, the cap tire cable 76 includes four-phase (4 phase) cables 91 to 94 for motor driving, MTP (Micro Thermal Protector) cables 95 and 96 for motor temperature detection, and electrode type. The signal line 87 of the liquid level detector 80 is covered with a tough rubber 90 to be integrated. Therefore, only one cap tire cable 76 is drawn out of the aeration device 20.

Operation operation of the aeration device

In operation of the aeration device 20, the motor 2 is driven, and the vanes 8 rotate in accordance with the rotation of the rotary shaft 13. By rotation of this vane 8, the to-be-processed liquid is sucked in the downward direction inclined with respect to the flow path 16 through the suction port 14. As shown in FIG. On the other hand, the air supplied from the blower (not shown) through the air supply pipe 11 is discharged into the air chamber 17, and then supplied to the processing liquid in the flow path 16 via the supply path 18 and stirred and mixed. . The mixed liquid containing bubbles is discharged from the discharge port 15 in the substantially horizontal direction by flowing through the flow path 16 while changing the flowing direction from the lower side to the horizontal direction.

Immersion Detection

When immersion occurs from the mechanical seal 6 or the like, the liquid to be treated gradually accumulates in the immersion storage chamber 70. And when the immersion amount of the immersion storage chamber 70 becomes more than a predetermined amount, the liquid level of the immersion storage chamber 70 will become more than a predetermined position, and the immersion occurrence will be detected by the liquid level detector 80. Specifically, when the liquid level of the submerged storage chamber 70 reaches or exceeds a predetermined position, a weak current flows between the electrode rod 81 and the electrode rod 81 through the liquid to be treated, and this current is a relay switch (not shown). Switch to abnormal signal (signal indicating abnormality). This abnormal signal is transmitted to a control system (not shown), and the control system executes a protective operation such as stopping the motor 2.

Effect of the Example

According to the present embodiment as described above, since the electrode type liquid level detector 80 constitutes a means for detecting immersion, the device size can be reduced and the material cost can be reduced. In addition, the accuracy and reliability of the immersion detection can be improved.

In addition, since the liquid level detector 80 is installed at the position between the lower bearing 4 and the mechanical seal 6, the water level can be detected before the liquid reaches the lower bearing 4, so that Immersion can be prevented.

Since the submerged storage chamber 70 separated from the motor chamber 40 is provided at the bottom of the motor chamber 40, the submerged processing liquid can be stored in the submerged storage chamber 70 at once. Damage can be more reliably prevented. In addition, since the immersion target liquid can be concentrated in the immersion storage chamber 70, the immersion detection becomes easy, so that the accuracy of the immersion detection can be improved.

Since the submerged storage chamber 70 is formed by the oil casing 3 constituting a part of the partition wall of the oil chamber 25, the number of parts can be reduced, thereby simplifying the construction and reducing the cost of the material cost.

The signal line 87 of the liquid level detector 80 extends between the stator 2a and the stator casing 1b to the adapter 75 on the upper part of the motor cover 1a, and together with the motor cable, the cap tire cable 76. In this configuration, the device configuration can be made simpler.

Modification example

The above embodiment is a form in which the vane 8 is directly connected to the motor 2, but the application target of the present invention is not limited to such a form, and the speed reducer is interposed between the motor 2 and the vane 8. It may be in the form.

The gas supplied to the to-be-processed liquid is not limited to air but may be another gas, for example, another oxygen-containing gas.

As described above, according to the present invention, by using the electrode type immersion detector, the device can be miniaturized and the material cost can be reduced. In addition, the immersion detection can be made with high accuracy, and the reliability of the device can be improved.

By installing the electrode type immersion detector below the bearing and above the mechanical seal, it is possible to detect the occurrence of immersion before the infiltrated liquid reaches the bearing, thereby enabling quick and effective immersion measures.

By forming the submerged storage chamber at the bottom of the motor chamber, it is possible to prevent the liquid to be directly introduced into the motor. In addition, the detection accuracy can be improved by performing the immersion detection in the immersion storage chamber.

By providing an auxiliary casing which stores the bearings and partitions the submerged storage chamber, it is possible to simplify the configuration due to the common use of the parts.

By drawing the signal line of the electrode type immersion detector from the upper part of the motor casing to the outside through the motor casing and the stator, the device configuration can be made simpler. By storing the signal line of the electrode type immersion detector together with the motor cable inside the cap tire cable, the device configuration can be simplified and the reliability of the device can be improved.

Claims (6)

A motor casing which forms a motor compartment for watertightly accommodating the motor, A motor rotating shaft installed on the motor so as to protrude from the motor casing; A vane fixed to the motor shaft, An aeration device having an apparatus casing for forming a flow path for stirring and mixing a liquid to be sucked by rotation of the vane with a predetermined gas and discharging it, An aeration device including an electrode type immersion detector for detecting the immersion of the motor chamber. The method of claim 1, The motor rotation shaft is provided with a mechanical seal and a shaft support that supports the motor rotation shaft above and below the motor. And a detecting portion of the electrode type immersion detector is provided above the mechanical seal and below the bearing. The method of claim 1, The motor is installed above the van, At the bottom of the motor chamber, a submerged storage chamber partitioned from this motor chamber is provided. The aeration apparatus of the electrode type immersion detector is provided in the said immersion storage chamber. The method of claim 2, The motor is installed above the van, At the bottom of the motor chamber, an auxiliary casing for storing the shaft support and partitioning the submerged storage chamber partitioned from the motor chamber is provided. The aeration apparatus of the electrode type immersion detector is provided in the said immersion storage chamber. The method according to any one of claims 1 to 4, The motor has a stator fixed inside the motor casing and a rotor installed inside the stator, And the signal line of the electrode type immersion detector is led outward from the top of the motor casing through the motor casing and the stator. The method according to any one of claims 1 to 4, And the signal line of the electrode type immersion detector is housed inside the cap tire cable together with a motor cable for supplying electric power to the motor.