JPH09126148A - Delivery monitoring device for gear pump - Google Patents

Abstract

PROBLEM TO BE SOLVED: To conveniently and precisely measure and monitor the delivery of a reciprocating pump which slightly varies. SOLUTION: In a device composed of a small capacity reciprocating pump for sucking a solution to be processed, such as chemicals from a supply tank for chemicals or the like and discharging the chemicals to a predetermined station (supply part) in a plant, a measuring pipe line system 14 including a measuring cylinder 20 opened to the atmosphere is incorporated in a suction pipe line system 14 for communicating the reciprocating pump 12 with the chemicals tank, and a pump delivery measuring means 50 measures a delivery of the chemicals from the pump in accordance with a measuring operation signal (an operation signal obtained from level meter 22) obtained from the measuring cylinder 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge flow rate monitoring device for a reciprocating pump, and more particularly to a discharge device for a reciprocating pump having a relatively small capacity used for a chemical injection device for water quality control in electric power or chemical plants. The present invention relates to a flow rate monitoring device.

[0002]

2. Description of the Related Art Generally, a chemical injection device for water quality adjustment is
As described above, the chemical solution in the supply tank is normally injected into a predetermined location in the plant via a reciprocating pump having a relatively small capacity.

Incidentally, in this type of water quality control chemical injection device, the injection amount of the chemical must be set to a predetermined amount corresponding to the water quality in the plant. However, in such a chemical injection device, the injection amount of the chemical, that is, the pump discharge flow rate, the pump characteristic, that is, the discharge capacity of the reciprocating pump, is set from the stroke length and the number of strokes of the reciprocating plunger. And has excellent quantification. At the same time, since the discharge capacity of the pump can be changed relatively easily, the predetermined amount can be set relatively easily.

[0004]

However, the above-described reciprocating pump, that is, the reciprocating pump having a relatively small capacity used in the injection device of the water quality adjusting chemical, has the following drawbacks.

As described above, the injection amount of the chemical in the injection device, that is, the pump discharge flow rate is set to a predetermined amount corresponding to the water quality in the plant. Further, the predetermined set amount has become smaller and smaller in recent years, and highly accurate change setting is required. However, the conventional reciprocating pump is
It was practically impossible to meet the above requirements.
That is, the discharge flow rate of the conventional reciprocating pump is generally calculated from the liquid level fluctuation amount of the liquid level meter provided in the chemical liquid supply tank to which the reciprocating pump is connected.

Incidentally, a normal flow meter used in a pump piping system has a pulsation, and further, for the piping system of the reciprocating pump of this kind which requires the minute amount and high precision change, Although not suitable for use, the measurement by this calculation is not only complicated in operation but also lacks in accuracy.
Therefore, as a result, the above-described pump discharge flow rate, that is, the accuracy of setting the chemical injection amount cannot be sufficiently increased.

As a means for solving the above-mentioned problems, for example, a new technique (Japanese Utility Model Publication No. 6-39102) disclosed by the present applicant is disclosed. However, this technology
It is specially processed within the pump body of a specific reciprocating pump (diaphragm pump), and therefore cannot be generally and simply applied to a general reciprocating pump of this type.

SUMMARY OF THE INVENTION An object of the present invention is to provide a reciprocating pump discharge flow rate monitoring device capable of measuring and monitoring a minute and fluctuating discharge flow rate of a reciprocating pump easily and highly accurately.

[0009]

In order to achieve the above object, a discharge flow rate monitoring device for a reciprocating pump according to the present invention sucks a handling liquid from a supply tank and discharges the handling liquid toward a supply section. In a small-capacity reciprocating pump configured as described above, a metering piping system including an atmosphere open type measuring cylinder is provided in a suction piping system that communicates the reciprocating pump and the supply tank, and a metering obtained by the metering cylinder is provided. A switching control means for performing an operation control of the reciprocating pump and a switching control of the switching valve based on an operation signal, and a pump discharge flow rate measuring means for measuring a pump discharge flow rate based on the metering operation signal are provided. And

In this case, the metering cylinder may be provided with a level meter for measuring the flow rate of the handling liquid flowing into and out of the cylinder.

Further, the switching control means is configured to control the operation of the reciprocating pump installed in the suction piping system or the metering piping system and the switching control of the switching valve according to the operation signal of the level meter provided in the measuring cylinder. can do.

Further, the pump discharge flow rate measuring means calculates a deviation between the pump discharge flow rate set value within a predetermined time and the pump discharge flow rate measured value measured based on the operation signal of the level meter provided in the measuring cylinder. Then, the system can be configured so that the deviation is compared with a predetermined allowable value and an alarm output is generated when the deviation is larger than the allowable value.

In the present invention, when the metering piping system is connected to the reciprocating pump by the switching control means, the liquid to be handled in the supply tank first flows into the atmosphere-releasing metering cylinder,
After once rising to a predetermined level in the measuring cylinder, it is lowered in the measuring cylinder and discharged into the reciprocating pump. At the time of this downward discharge, the pump discharge flow rate measuring means operates based on the operation signal of the level meter in the measuring cylinder, so that the downward discharge flow rate (pump discharge flow rate).
Is automatically measured for a predetermined time. That is, in this case, the pump discharge flow rate can be continuously and highly accurately measured even if the flow rate pulsates and fluctuates in a very small amount.

Further, in the present invention, the pump discharge flow rate measuring means can be installed in the suction piping system for the supply tank of the reciprocating pump, so that the main equipment such as the pump is not changed and the existing equipment is installed. Even equipment can be generally and simply additionally applied to this type of general reciprocating pump.

Therefore, in the present invention, the required injection amount of the handling liquid such as the chemical liquid is constantly calculated, and the stroke length and the rotational speed (stroke number) of the pump are constantly adjusted so as to match them, and the set flow rate is constantly changed. Under varying conditions, it is possible to check whether the actual flow rate matches the fluctuating set flow rate, and it is possible to check for obstacles such as airlock.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the discharge flow rate monitoring device for a reciprocating pump according to the present invention will be described in detail below with reference to the accompanying drawings.

In FIG. 1, first, the discharge flow rate monitoring device of the reciprocating pump according to the present invention is preferably applied to a water quality adjusting chemical injection device or the like as described above. Then, basically, the handling liquid such as the chemical liquid is sucked from the supply tank 10 for the chemical liquid and the chemical liquid is supplied to a predetermined portion (supply unit) in the plant.
A device consisting of a small-capacity reciprocating pump 12 for discharging to a supply tank 10 of the reciprocating pump 12.
In the suction pipe system 14 including a metering pipe system 30 including an atmosphere open type metering cylinder 20 bypassing from the suction pipe system 14 and communicating with the supply tank 10, and the reciprocating operation based on a metering operation signal of the metering cylinder 20. Dynamic pump 12
Switching control means 40 for controlling the operation of the control valve and switching control of the switching valve, and pump discharge flow rate measuring means 5 for measuring the pump discharge flow rate based on the metering operation signal and monitoring the abnormality.
0 and 0 are provided.

Therefore, each of the above-mentioned components will be described in detail below.

First, the metering cylinder 20 having the atmosphere vent vent 20a communicates with the supply tank 10 and the metering piping system 30 via the communication pipes 20b and 20c, respectively, and measures the flow rate of the chemical solution therein. For this purpose, a magnetostrictive level meter 22 is provided. The metering cylinder 20 has, for example, a reference discharge amount of the reciprocating pump 12 of 3 l.
In the case of / min, the cylinder body is set to, for example, 5 l (area 80 A x height 1 m). The magnetostrictive level meter 22 has four operating contacts LL, L, H,
HH is provided. In this case, the operating contacts L and H are set points, and LL and HH are limit points. The magnetostrictive level meter 22 can output a liquid level signal in an analog manner according to the liquid level in the measuring cylinder 20.

Next, the switching control means 40 is used for the suction piping system 1.
4 is provided with two electromagnetic (or pneumatic) actuating valves 24, 26 in the metering piping system 30 bypassed from 4, and four actuating contacts LL, L set for the level meter 22.
H, HH having operating points corresponding to the two operating valves 2
4, 26 and each operation part of the reciprocating pump 12 and a switching controller 42 connected by a control line.
The actuating valves 24 and 26 are of a high-frequency type that operates instantaneously (almost the same diameter as the piping system), and the switching controller 42 is used.
Can be composed of, for example, a personal computer or a digital controller. Further, reference numeral 16 in FIG. 1 indicates a manually or automatically operated valve provided in the suction piping system 14 corresponding to the operation valves 24 and 26.

Therefore, in the switching control means 40 having such a structure, when the start push button switch 42a is operated while the operation valve 16 of the suction piping system 14 is closed, the switching control unit 42 causes both the operation valves 24, 26 opens, and the metering piping system 30 communicates with the reciprocating pump 12. As a result, the chemical liquid in the supply tank 10 is released into the atmosphere, and the measuring cylinder 20 is opened.
When the chemical flows into the inside of the supply tank 10 and rises to a predetermined level in the supply tank 10 (the upper operating contact H of the level meter 22 in the corresponding measuring cylinder 20), the level meter 22 operates and is switched by this operation signal. Via the controller 42,
The operation valve 24 is closed. Then, when the reciprocating pump 12 is activated, the chemical liquid in the measuring cylinder 20 is lowered and discharged. At this time, while the flow rate of the chemical liquid that is lowered in the measuring cylinder 20 and discharged to the pump 12 side (actual discharge flow rate Qa of the pump) is the predetermined time T (for example, 1 minute or 2 minutes), It is automatically measured by the pump discharge flow rate measuring means 50 based on the operation signal of the level meter 22.

That is, in the case of a reciprocating pump, the instantaneous discharge flow rate is the pump discharge quantity Q _max × the pump stroke length 1
₀ / l _max (%) x pump speed (stroke count) n
_{It is} theoretically obtained by ₀ / n _max (%). Therefore, if the discharge flow rate per minute is measured based on the theoretical value, the pump discharge flow rate Q ₀ (set value) can be obtained by the following equation.

[0023]

(Equation 1)

However, the pump discharge flow rate measuring means 50
Is shown as the system configuration in FIG. In the system configuration shown in FIG. 2, the discharge flow rate of the reciprocating pump 12 is measured and monitored by first setting the set pump discharge flow rate Q.
₀ [the set stroke length l ₀ , the set number of strokes n ₀ and the integrated value of the predetermined time T with respect to the maximum discharge amount Q _max ] are multiplied by the multipliers 51 and 52, respectively, and the predetermined time T by the timer calculator 53. Is calculated based on the arithmetic expression.

Pump discharge flow rate Q thus obtained
₀ is the actual discharge flow rate (determined by the set points L and H of the working contact of the level meter 22 in the measuring cylinder 20) Qa
The deviation is calculated by the subtractor 54, and the obtained deviation is compared with a predetermined allowable value m by the comparator 55 to perform the calculation. Therefore, in this case, if the deviation obtained in the comparator 55 is larger than the allowable value m, an alarm output is generated, and the pump output flow rate measuring means 5 is appropriately output by this alarm output.
It is possible to operate the alarm device 56 and the like provided outside 0.

Thus, in the device of the present invention,
The pump discharge flow rate per predetermined time can be calculated by detecting the liquid level drop of the measuring cylinder during the predetermined time (measured by a magnetostrictive level meter). And
It is also possible to check the injection (discharge) integrated amount (usage amount) for a long time unit by detecting the number of times of measurement by the measuring cylinder based on the operation signals at the set points H and L by the level meter. . Therefore, even if the discharge flow rate of the pump pulsates and fluctuates, it is possible to perform highly accurate measurement and monitoring. The pump discharge flow rate measuring means 50 thus configured can be shared by, for example, a personal computer or the like which constitutes the switching control means 40.

In the present invention, since the pump discharge flow rate measuring means 50 is installed in the suction pipe system 14 for the supply tank 10 of the reciprocating pump 12 as described above, a general reciprocating operation of this type is performed. It is also clear that the dynamic pump can be generally and simply additionally applied to the dynamic pump (in this case, the main equipment such as the pump is not changed and even the existing equipment).

In the embodiment shown in FIGS. 1 and 2, the measuring cylinder 20 is connected to the suction piping system 14.
Although the configuration is shown in which the measuring pipe system 30 is bypassed from the above, the measuring pipe system 30 including the measuring cylinder 20 may be provided to the suction pipe system 14. That is,
When the metering piping system 30 is used as a bypass line, the chemical liquid flows in or out of the metering cylinder 20 (flow rate measurement).
By closing the valve 16 only when the operation is performed, the pump discharge flow rate can be measured without stopping the operation. On the other hand, when the measuring cylinder 20 is directly provided in the suction pipe system 14, the measuring cylinder 20 is provided on the downstream side of the valve 16, and the valve is provided only when the chemical liquid flows into or out of the measuring cylinder 20 (flow rate measurement). By closing 16, the pump discharge flow rate can be measured without stopping the operation.

However, when the measuring pipe system 30 is used as a bypass line, it is convenient for inspection and cleaning of the measuring cylinder 20.

Incidentally, the vent portion 20a of the measuring cylinder 20 of the present invention is effective as an airlock countermeasure when a harmful chemical such as hydrazine is used.

Further, in the present invention, as means for measuring the pump discharge flow rate by the pump discharge flow rate measuring means,
Instead of the method of setting the measurement time described above, a method of previously setting the number of strokes or the like can be applied. That is, the method of setting the stroke number is such that the rotation speed sensor is provided on the reciprocating pump side (for example, an encoder is attached to the piston actuating cam shaft that drives the pump), so that the measurement period of the pump discharge flow rate is changed to not the time. Set by the number of strokes. As a result, for example, an accurate pump discharge flow rate can be obtained from the liquid level reduction amount during one stroke. In this case, it is not necessary to set the set points L and H which are the operating contacts by the level meter, and it is effective to check the injection (discharge) integrated amount (usage amount) for a long time unit.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and many design changes can be made without departing from the spirit of the present invention. That is, for example, the two two-way actuating valves forming the switching valves 24 and 26 in the metering piping system may be configured as one three-way actuating valve provided at the connection branch point of the metering cylinder 20. Further, the switching valve 26 may be provided in a branch line to which the measuring cylinder 20 is connected.

[0033]

As described above, the discharge flow rate monitoring device for a reciprocating pump according to the present invention is a small volume reciprocating device configured to suck the handling liquid from the supply tank and discharge the handling liquid toward the supply section. In a dynamic pump, a metering piping system including an atmosphere open type measuring cylinder is provided in a suction piping system that connects the reciprocating pump and the supply tank, and the reciprocating motion is performed based on a metering operation signal obtained by the metering cylinder. Switching control means for controlling the operation of the pump and switching control of the switching valve, and pump discharge flow rate measuring means for measuring the pump discharge flow rate based on the metering operation signal and monitoring the abnormality are provided. As a result, when the metering piping system communicates with the reciprocating pump through the switching control means, the liquid to be handled in the supply tank first flows into the atmosphere-releasing metering cylinder and reaches a predetermined level. After rising to Le, and discharged to the reciprocating pump side is lowered in the cylinder, then on the basis of the operation signal from the level meter in the cylinder during this lowering emissions,
When the descending discharge flow rate (pump discharge flow rate) is within a predetermined time,
It can be automatically measured by the pump discharge flow rate measuring means.

That is, according to the present invention, during the normal operation of the reciprocating pump, the accuracy of the pump discharge flow rate can be automatically checked by the batch method, and the abnormality of the discharge flow rate can also be automatically checked. can do. Further, even if the discharge flow rate of the pump pulsates and fluctuates in a very small amount, the pump discharge flow rate can be measured with high accuracy and the abnormality of the discharge flow rate can be monitored.

Further, in the present invention, since the pump discharge flow rate measuring means can be installed in the suction pipe system for the supply tank of the reciprocating pump, in comparison with a general reciprocating pump of this type (in this case, , The main equipment such as a pump is not changed, and even existing equipment can be applied generally and easily.

[Brief description of the drawings]

FIG. 1 is a schematic explanatory diagram of an overall configuration showing an embodiment of a discharge flow rate monitoring device for a reciprocating pump according to the present invention.

FIG. 2 is a system configuration diagram showing a measurement and monitoring system of pump discharge flow rate measuring means in the discharge flow rate monitoring device shown in FIG.

[Explanation of symbols]

 10 Supply Tank 12 Reciprocating Pump 14 Suction Piping System 16 Valve 20 Metering Cylinder 20a Vent 20b Communication Pipe 22 Level Meter 24, 26 Actuating Valve 30 Metering Piping System 40 Switching Control Means 42 Switching Controller 42a Push Button Switch 50 Pump Discharge Flow Rate Measuring means 51, 52 Multiplier 53 Timer calculator 54 Subtractor 55 Comparator 56 Alarm device

Claims (4)

[Claims] 1. A small-capacity reciprocating pump configured to suck a handling liquid from a supply tank and discharge the handling liquid toward a supply unit, in a suction piping system that connects the reciprocating pump and the supply tank. And a switching control means for performing operation control of the reciprocating pump and switching control of the switching valve based on a metering operation signal obtained by the metering cylinder. A discharge flow rate monitoring device for a reciprocating pump, comprising: pump discharge flow rate measuring means for measuring a pump discharge flow rate based on a metering operation signal. 2. The discharge flow rate monitoring device for a reciprocating pump according to claim 1, wherein the metering cylinder is provided with a level meter for measuring the flow rate of the handled liquid flowing into and out of the cylinder. 3. The switching control means is configured to perform operation control of a reciprocating pump installed in a suction piping system or a metering piping system and switching control of a switching valve according to an operation signal of a level meter arranged in a measuring cylinder. The discharge flow rate monitoring device for a reciprocating pump according to claim 1. 4. A pump discharge flow rate measuring means calculates a deviation between a pump discharge flow rate set value within a predetermined time and a pump discharge flow rate measured value measured based on an operation signal of a level meter provided in a measuring cylinder. 2. The discharge flow rate monitoring device for a reciprocating pump according to claim 1, wherein the deviation is compared with a predetermined allowable value, and a system is configured to generate an alarm output when the deviation is larger than the allowable value. .