JPH0332792A - Method for controlling vacuum pump of deoxidation system - Google Patents

Abstract

PURPOSE:To decrease the noises occurring in the cavitation phenomenon generated in the water sealed vacuum pump which operaters in association with the flowing water detection in a feed water time of the deoxidation system for cold and hot apparatus as well as the loss of the pump driving power by controlling the driving of the above-mentioned pump. CONSTITUTION:The flow in the feed water line 3 is detected by a flow switch 6 and the water sealed vacuum pump 7 is driven in response with the detection output signal thereof; in addition, a 1st solenoid valve 11 provided in a sealing water supply line 8 and a 2nd solenoid valve 13 provided in a deaeration line 9 connecting a deoxidation module 5 and the water sealed vacuum pump 7 are opened. The outputting of the output signal of the flow switch 6 is so controlled as to open the 1st solenoid valve 11 upon lapse of delay time after the 2nd solenoid valve 13 is opened by a controller 12. The excess flow of the sealing water into the water sealed vacuum pump at the time of restarting is, therefore, prohibited and the noises occurring in the cavitation at the time of the excess flow-in of the sealing water and the loss of the pump driving power are decreased.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a deoxidation system applied in a water supply line to a cooling and heating equipment, and in particular relates to the detection of flowing water in a water supply line. The present invention relates to a method for controlling a water ring vacuum pump in a deoxidation system that controls the driving of a water ring vacuum pump.

[Prior Art] As is well known, when supplying water to cooling equipment such as boilers, water heaters, and coolers, it is necessary to incorporate an oxygen removal system for the purpose of preventing corrosion of the cooling equipment. In the deoxidation system, a deoxidation module is connected to the water supply line to the equipment used, and raw water (tap water, well water, other industrial water) is passed through the deoxidation module. During the process, the inside of the deoxidizing module is vacuumed to remove gas dissolved in the raw water.

Conventionally, in this deoxidizing system, a water ring type vacuum pump, which has a simple structure and is inexpensive, has been frequently used as a means for evacuation processing. The water ring vacuum pump is, for example,
An appropriate amount of sealed water is placed in a casing with an oval pump chamber, and as the impeller rotates, the water is flowed along the inner wall of the casing by centrifugal force, creating an oval air space in the center of the casing. This is a device that creates a space and performs suction and discharge by displacement of the space as the impeller rotates.

[The problem that the invention tries to solve! IJ The conventional deoxidation system, as shown in Figure 2, consists of a deoxidation module (25) and a flow switch (26) connected to the water supply line (23), a water supply line (23) and a sealed vacuum pump ( Water seal supply line (28) between
A solenoid valve (31) for a water seal installed inside the tank, and a solenoid valve (31) installed inside the degassing vacuum line (29) between the deoxidation module (25) and the water ring vacuum pump (27) for maintaining vacuum during shutdown. solenoid valve(
33>, and when water is supplied into the water supply line (23), the flow switch (26) is activated,
A flowing water detection signal is output, and in response to the output signal, the water ring type vacuum pump (27) is driven, and the two electromagnetic valves (31) and (33) are opened to perform vacuum degassing. When the water supply stops, the water ring vacuum pump (27) stops and the two electromagnetic valves (31) and (33) close.

When water supply starts again to the water supply line (23), the flow switch (26) is activated, and in response to its output signal, the water ring vacuum pump (27) is driven, and the two solenoid valves (31) are activated. ), (33) to restart vacuum degassing. In this case, during the previous vacuum deaeration operation, the deoxidation module (2
5) to the solenoid valve (33) for maintaining vacuum during stoppage is maintained in a vacuum state, so the water sealing supply line (2
8) The sealed water from the side is pumped by the vacuum pump (2) by negative pressure action.
7> will rapidly flow into the interior. As described above, this type of water-ring vacuum pump <27> operates when a certain amount of water flows inside the pump casing along the inner wall of the casing. However, when a large amount of sealed water suddenly flows into the casing, as at the time of restart described above, it becomes difficult to create a space at the base of the impeller. Furthermore, since the sealed water is constantly supplied from the water supply side via the constant flow valve (30), there are cases where the system does not shift to a steady operating state in which a predetermined amount of sealed water flows along the inner wall of the casing. In this state, noise is generated due to cavitation inside the pump, and the pump driving power also increases. To get rid of cavitation, etc., air can be introduced into the vacuum pump. There were problems in that power loss increased and the residual value of dissolved oxygen in the treated water increased.

Therefore, this invention controls the drive of a water ring vacuum pump that operates in connection with the detection of flowing water in a water supply line in a deoxidation system for cooling and heating equipment. It is an object of the present invention to provide a vacuum pump control method in a deoxidation system that prevents the generation of noise and loss of pump drive power due to cavitation phenomena and the like.

[Means for Solving the Problems J] In order to achieve the above-mentioned object, the present invention specifically provides a water supply line between a raw water supply source and a treated water supply section, in which dissolved gases in the raw water are removed. A deoxidation module that removes water and a flow switch that detects flowing water in the water supply line and outputs an electric signal are connected, and sealed water is introduced through a sealed water supply line connected to the water supply line to the deoxidation module. A water seal vacuum pump is connected to the water seal via a vacuum degassing line and is driven in response to the output signal of the flow switch; To open the road,
a first valve provided in the sealed water supply line; and a second valve provided in the vacuum deaeration line to open a flow path in the vacuum deaeration line in response to an output signal of the flow switch. In the deoxidation system, after a preset delay time has elapsed after opening the second valve in response to the output signal of the flow switch,
This is a method for controlling a vacuum pump in a deoxidation system, in which the first valve is opened to prevent excessive flow of seal water into the water ring type vacuum pump when the water ring type vacuum pump is restarted.

[Function 1] In the vacuum pump control method in the deoxidation system of the present invention configured as described above, a flow switch is connected in the water supply line, and when the flow switch detects the flow in the water supply line, a first valve that drives a water ring vacuum pump in response to the detection output signal and is provided in a water seal supply line to the water ring vacuum pump;
Open the second valve provided in the vacuum deaeration line connecting the deoxidation module and the water ring vacuum pump. In this case, the output signal of the flow switch is transmitted to the second
After the delay time has elapsed, the first valve is opened.
The output is controlled to open the valve, which prevents excessive flow of seal water into the water ring pump when restarting, and reduces noise caused by cavitation when excessive flow of seal water occurs.
It also reduces the loss of pump drive power.

[Description of Embodiments] Hereinafter, a method for controlling a vacuum pump in a deoxidizing system according to the present invention will be described in detail based on specific embodiments shown in the drawings.

FIG. 1 shows a preferred example of an apparatus for the water ring vacuum pump control method of the present invention. This device includes a pressure reducing valve (4), a deoxidation module (
5) and a flow switch (6). The pressure reducing valve (4) prevents supply water pressure above a certain level from being applied to the deoxidizing module (5), and is intended to prevent damage to the deoxidizing module (5). 5), for example, is equipped with a large number of hollow fiber membranes, passes raw water through the inside of the hollow fiber membranes, draws a vacuum on the outside, and removes dissolved oxygen in the raw water during the process of water passing through the hollow fiber membranes. The so-called hollow fiber membrane deoxidation module that removes
Alternatively, a sheet-like filtration member formed in the form of a laminated sheet,
It may also be a deoxidation module rolled up into a roll.

The flow switch (6) is connected to the outlet side of the deoxidation module in the water supply line (3), and detects flowing water supplied from the water supply line (3) into the deoxidation module (5). It is designed to output an electrical signal.

On the other hand, in the present invention, a water ring type vacuum pump (7) is applied as a means for vacuum degassing the deoxidation module (5). The water ring type vacuum pump (7) is connected to the water supply line (3) through a water seal supply line (8>), and is connected to the water ring type vacuum pump (7) to provide vacuum deaeration to the deoxidation module (5>). The water ring type vacuum pump (7) is electrically connected to the flow switch (6), and is connected to the flow path via a line (9).
) is activated in response to the output signal of the The water sealing supply line (8) is provided with a constant flow valve (10) and a first electromagnetic valve (11). The constant flow valve (10) is for supplying a fixed amount of sealed water to the water ring vacuum pump (7). The first electromagnetic valve (11) is electrically connected to the flow switch (6) via a controller (12), and the flow switch (6) allows flowing water to flow in the water supply line. When the detection occurs, after a delay time preset in the controller (12) has elapsed, the valve opens in response to the output signal, opens the sealed water supply line (8), and supplies the sealed water to the water. Supplied into the sealed vacuum pump (7).

On the other hand, the vacuum degassing line (9) is equipped with a second electromagnetic valve.
13> is the provision. The second electromagnetic valve (13) is electrically connected to the flow switch (6), and opens in response to a detection signal when the flow switch (6) detects running water. speak. When the second electromagnetic valve (13) is opened, the oxygen removal module (
5) is communicated with a water ring vacuum pump (7) via a vacuum degassing line (9), and the deoxidation module (5) is evacuated.

The water ring type vacuum pump (7) is equipped with a discharge line (14), and discharges water supplied into the water ring type vacuum pump (7) via the discharge line (14), and Gas is exhausted by vacuuming.

[Effects of the Invention] In the configuration described above, according to the present invention, the opening timing of the first electromagnetic valve (11) provided in the water sealing supply line (8) is adjusted to the timing for opening the first electromagnetic valve (11) provided in the vacuum degassing line (9>). From the opening timing of the solenoid valve 2 (13), the controller (1
By delaying the delay time set in step 2) and slowing down the supply of seal water sent to the water ring vacuum pump (7) via the water seal supply line (8), the water ring vacuum pump (7) This suppresses the cavitation phenomenon inside the pump, thereby reducing the noise caused by the cavitation phenomenon and the loss of pump drive power.

[Brief explanation of drawings]

Figure 1 is a block diagram of a specific device example that effectively operates on the vacuum pump control method in the deoxidation system of the present invention, and Figure 2 is a conventional example of deoxidation using a water ring vacuum pump. FIG. 2 is an explanatory diagram of the system. (1)... Raw water supply source (2>... Treated water supply section (3)... Water supply line (5>... Oxygen removal module ( 6)...Flow switch (7)...Water ring vacuum pump (8)...Water seal supply line (9>...Vacuum deaeration line (11)...First electromagnetic valve (12)...
... Controller (I3) ... Second electromagnetic valve Fig. Fig.

Claims (1)

[Claims] A deoxidation module that removes dissolved gas in the raw water is provided in a water supply line between a raw water supply source and a treated water supply section, and a deoxidation module that detects flowing water in the water supply line and outputs an electrical signal. a flow switch connected to the deoxygenation module, which takes in sealed water via a sealed water supply line connected to the water supply line, and is connected to the deoxidation module via a vacuum degassing line;
a water ring type vacuum pump driven in response to an output signal of the flow switch; and a water ring vacuum pump provided in the water seal supply line so as to open a flow path of the water seal supply line in response to the output signal of the flow switch. and a second valve provided in the vacuum degassing line to open a flow path in the vacuum degassing line in response to an output signal of the flow switch. , After opening the second valve in response to the output signal of the flow switch, after a preset delay time elapses,
A method for controlling a vacuum pump in a deoxidation system, characterized in that the first valve is opened to prevent excessive flow of seal water into the water ring vacuum pump when restarting.