JP2004117153A - Instrument and method for measuring volume - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an instrument and method for measuring volume, by which the productivity of a product can be improved by appropriately confirming the airtightness of the hollow section of a work. <P>SOLUTION: When the advance to a measuring step is ready, by filling up first and second gauge tanks 6 and 7 with compressed air and confirming that the internal pressures of the tanks 6 and 7 are equivalent to each other, communication between the first gauge tank 6 and a compressed air supply device 2 is interrupted, and the work 16 is inspected for airtightness by supplying compressed air from the compressed air supply device 2 to the work 16 via a passage member 13 by opening an airtightness confirming-side valve 26. When airtightness of the work 16 is secured, the measuring step is started, but when leakage is detected, the measuring step is started, after preparing measuring conditions. Since the airtightness inspection is performed, before the measuring step unlike the conventional technology by which volume measurement is performed, even if the compressed air leaks out and time losses are caused due to the remeasurements, productivity can be improved by avoiding the remeasurements. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a volume measuring device and a volume measuring method used for measuring the volume and the like of an automobile transmission and a differential oil case of a vehicle.
[0002]
[Prior art]
FIG. 3 shows an example of a conventional volume measuring device. In FIG. 3, a volume measuring device 1 includes a compressed air supply device 2 for supplying compressed air, a compressed air supply passage 3 for guiding compressed air discharged from the compressed air supply device 2, and a branch from the compressed air supply passage 3. First and second passages 4 and 5 and two gauge tanks of equal capacity which are connected to the first and second passages 4 and 5 and store compressed air, respectively (referred to as first and second gauge tanks, respectively). .) 6, 7 and two electromagnetic three-way valves (hereinafter, referred to as first and second electromagnetic three-way valves) 8, 9 provided in the middle of the first and second passages 4, 5, respectively. .
[0003]
A differential pressure sensor 10 is connected to portions of the first and second passages 4 and 5 on the first and second gauge tanks 6 and 7 side. The passage connecting the tank 6 with the valve 8 and the differential pressure sensor 10 and the passage connecting the tank 7 with the valve 9 and the differential pressure sensor 10 have the same volume, and the volume of the passage connecting the valve 9 and the master tank 20 is known. It has been. Further, a pressure sensor (hereinafter, referred to as a second passage-side pressure sensor) 11 is provided so as to be connected to a portion of the second passage 5 on the second gauge tank 7 side. One port of the first electromagnetic three-way valve 8 is connected to one end of a main tube 14 that forms a passage member 13 together with a measurement nozzle 12 described later. The measuring nozzle 12 is connected to the other end of the main tube 14. The measurement nozzle 12 is mounted on an opening 17 of a work 16 (container) having a hollow portion 15. An air seal member (not shown) is attached to the measurement nozzle 12 to improve airtightness. An oil 18 (liquid) is stored in the hollow portion 15 of the work 16. The opening 16 is provided in the work 16 so as to communicate with a space portion (hereinafter, appropriately referred to as a space portion) 19 on the liquid in the hollow portion 15.
One port of the second electromagnetic three-way valve 9 is connected to a master tank 20 having a fixed volume. The switching operation of the second electromagnetic three-way valve 9 allows the master tank 20 to communicate with the second gauge tank 7.
[0004]
In the volume measuring device 1, first, the work 16 (main tube 14) is shut off from the first passage 4 and the master tank 20 is shut off from the second passage 5 via the first and second electromagnetic three-way valves 8 and 9. In this state, the compressed air supply device 2 is communicated with the first and second gauge tanks 6 and 7 to fill the first and second gauge tanks 6 and 7 with compressed air (charging step), and then the first and second gauge tanks 6 and 7 are charged. (2) Activate the electromagnetic three-way valves (8, 9) to shut off the compressed air supply device (2) from the first and second gauge tanks (6, 7). Confirm that the pressure is “zero” (differential pressure confirmation step).
Next, after the measurement nozzle 12 is mounted on the opening 17 of the work 16 (measurement nozzle 12 mounting step), the first and second electromagnetic three-way valves 8 and 9 are operated to connect the first gauge tank 6 and the work 16. The second gauge tank 7 and the master tank 20 are communicated with the hollow portion 15 and the work side circuit (the circuit including the work 16 and the first gauge tank 6) and the master tank side circuit (the master tank 20 and the second tank). The volumes are compared based on the differential pressure of the circuit including the 2-gauge tank 7), and the volume of the work-side circuit and thus the space 19 of the work 16 is measured (measurement step). After the measurement, the measurement nozzle 12 is detached from the work 16 and the measurement nozzle 12 is attached to the opening of the next work to be measured.
In the measurement process, the measurement nozzle 12 is attached to the opening 17 of the work 16 for each measurement. When the measurement nozzle 12 is mounted, the hollow portion 15 of the work 16 is made airtight.
[0005]
As a conventional example of detecting the volume based on the differential pressure in the same manner as described above, there is a catalog shown in the second page of the catalog of "Voltech automatic measurement" by ATEC Corporation.
[0006]
[Non-patent document 1]
ATEC Corporation (3-41 Ikehata, Chiryu-shi, Aichi Prefecture, Atec Building tel: 0566-84-4670 http://www.ateq.com) Catalog of “Voltech volume automatic measurement” (not published date), 2nd Page [0007]
[Problems to be solved by the invention]
By the way, in the above-described conventional technology, the hollow portion 15 of the work 16 is made airtight by the measurement nozzle 12, but the state cannot be visually observed, which causes anxiety.
Further, when the air seal member attached to the measurement nozzle 12 is damaged, or when the measurement nozzle 12 is not properly attached to the opening 17 of the work 16, the hollow portion 15 of the work 16 is airtight. However, the measurement process is performed in such a case. Then, if the measurement is performed in a state in which the airtightness is not obtained, the airtightness becomes "defective", and the remeasurement is required. In this case, the time required for re-measurement (re-measurement time), that is, the charge time (for example, 15 seconds) required for the charging step and the measurement time (for example, 3 seconds) required for the measurement step become a loss time in the production process, and This will lead to a decline.
[0008]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a volume measurement device and a volume measurement method capable of properly checking the airtightness of a hollow portion of a work and improving productivity. And
[0009]
[Means for Solving the Problems]
The invention according to claim 1 is a measurement-side container section that includes a reference-side container section in which a compressed gas is sealed and a passage member connected to a space of a work in which a liquid is stored in a hollow section and in which the compressed gas is sealed. A volume measurement device that has a differential pressure detection unit that detects a pressure difference between the reference-side container unit and the measurement-side container unit, and that measures the volume of the space using the pressure difference, An airtightness check circuit for checking the airtightness of the passage member and the work is provided.
According to a second aspect of the present invention, in the configuration according to the first aspect, the passage member includes a main tube and a measurement nozzle having one end connected to the main tube, and the measurement nozzle is attached to an opening of the work. The measurement-side container section includes a measurement-side tank having a predetermined volume for storing a compressed gas, a measurement-side main valve, and the passage member. The measurement-side main valve is configured to supply a compressed gas that supplies a compressed gas. The source, the measurement side tank and the main tube can be selectively communicated or shut off with each other, and the airtightness check circuit includes a pressure sensor provided to detect an internal pressure of the main tube. An airtightness confirmation side tube, one end of which is branched and connected to the main tube, and the other end of which is connected to the compressed gas supply source and guides compressed gas; An airtightness check side regulator that adjusts the pressure value of the compressed gas supplied to the main tube, an airtightness check side valve capable of communicating with and shutting off the main tube and the compressed gas supply source and communicating with the atmosphere of the main tube, It is characterized by comprising.
According to the first or second aspect of the present invention, the airtight state of the passage member and the work is checked by the airtightness check circuit, so that the compressed gas leaks and the work space is not properly measured. Volume measurement can be grasped prior to the measurement.
[0010]
According to a third aspect of the present invention, there is provided a measurement-side container section which includes a reference-side container section in which a compressed gas is sealed and a passage member connected to a space of a work in which a liquid is stored in a hollow section and in which the compressed gas is sealed. And a pressure difference detecting means for detecting a pressure difference between the reference-side container portion and the measurement-side container portion, and a volume measurement method for measuring the volume of the space portion using the pressure difference, comprising: A measurement nozzle mounting step of mounting the measurement nozzle of the passage member composed of a tube and a measurement nozzle to the opening of the work, and after mounting the measurement nozzle to the opening of the work, the measurement nozzle was connected to the main tube. An airtightness inspection step of measuring the internal pressure by a pressure sensor to inspect the airtightness of the passage member and the work, wherein the airtightness inspection step is performed prior to the measurement step of measuring the volume of the space. You .
According to a fourth aspect of the present invention, in the configuration of the third aspect, there is provided a selecting step of selecting whether to notify a poor airtightness or start a measuring step based on an inspection result of the airtightness inspecting step. It is characterized by.
According to the third or fourth aspect of the present invention, the airtightness inspection step for inspecting the airtightness of the passage member and the work is performed prior to the measurement step, so that the space of the work in a state where the measurement conditions are not established. Measurement of the volume of the object can be avoided.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
A volume measuring device and a volume measuring method according to a first embodiment of the present invention will be described with reference to FIG. Note that members equivalent to those shown in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted as appropriate. The volume measuring device 1A shown in FIG. 1 is mainly different from the volume measuring device 1 in FIG. 3 in that an airtightness check circuit 21 is provided.
As shown in FIG. 1, the airtightness check circuit 21 is connected to the main tube 14 via a branch tube 22 and detects a pressure inside the main tube 14 (hereinafter, referred to as a main tube side pressure sensor) 23; One end is branched and connected to the main tube 14, and the other end is connected in the middle of the compressed air supply passage 3, and the airtightness confirmation side tube guides compressed air (compressed gas) from the compressed air supply device 2 (compressed gas supply source). 24, an airtightness confirmation side regulator 25 provided in the middle of the airtightness confirmation side tube 24 to adjust the pressure value of the compressed air supplied to the main tube 14, and an airtightness with the main tube 14 in the airtightness confirmation side tube 24. An electromagnetic airtight check valve 26 provided between the check regulator 25 and the airtight check valve 26. The airtightness check side valve 26 communicates and shuts off the main tube 14 and the compressed air supply device 2 and can communicate the main tube 14 with the atmosphere. Note that a regulator (referred to as a discharge side regulator) 27 is provided at a portion of the compressed air supply passage 3 on the side of the compressed air supply device 2 upstream of the connection with the airtightness confirmation side tube 24.
[0012]
In this embodiment, the air pressure of the discharge side regulator 27 can be arbitrarily set, and the airtightness check pressure set by the airtightness check side regulator 25 is the second air pressure which is communicated via the second electromagnetic three-way valve 9 as described later. The pressure is set equal to the air pressure (test pressure) in the circuit including the gauge tank 7 and the master tank 20. The airtightness inspection pressure set by the airtightness side regulator 25 may be set to a value higher than the air pressure (test pressure) in order to quickly detect an air leak. The air pressure (test pressure) is detected by the second passage-side pressure sensor 11. Further, in this embodiment, the volume of the master tank 20 is set substantially equal to the volume of the hollow portion 15 of the work 16. Further, a work side portion 30 (to be in a state where the oil 18 is not stored in the work 16) and a master tank side portion 31 (reference side container portion) described later have substantially the same volume.
[0013]
A controller 32 is connected to the first and second electromagnetic three-way valves 8 and 9, the differential pressure sensor 10 (differential pressure detecting means), the second passage side pressure sensor 11, the main tube side pressure sensor 23, and the airtightness confirmation side valve 26. ing. The controller 32 performs a calculation based on a predetermined program with respect to input signals from the connection members (the differential pressure sensor 10, the second passage-side pressure sensor 11, and the main tube-side pressure sensor 23), as described later. The switching control of the connected valves (the first and second electromagnetic three-way valves 8 and 9 and the airtightness confirmation side valve 26) is performed, and the volume of the space 19 of the work 16 is measured.
In the present embodiment, the first gauge tank 6 constitutes a measurement-side tank, the first electromagnetic three-way valve 8 constitutes a measurement-side main valve, the first gauge tank 6 (measurement-side tank), and the first electromagnetic three-way valve. 8 (measurement-side main valve), a passage member 13 and a passage portion (reference numeral omitted) connecting the first gauge tank 6 and the first electromagnetic three-way valve 8 constitute a measurement-side container portion 40.
[0014]
Next, the operation of the volume measuring device 1A will be described.
First, a measurement nozzle 12 provided with a seal member (not shown) is attached to an opening 17 of a work 16 in which an oil 18 (liquid) is stored in a hollow portion 15, and the hollow portion 15 of the work 16 is sealed. (Measurement nozzle mounting process). Then, with the hollow portion 15 of the work 16 (main tube 14) blocked from the first passage 4 and the master tank 20 blocked from the second passage 5, the compressed air supply device 2 and the first and second gauge tanks 6 are closed. , 7 are set to communicate with each other, and in this set state, a start button (not shown) is pressed to start the compressed air supply device 2 to start the first and second gauge tanks. Compressed air is supplied to the tanks 6 and 7 for a certain period of time to fill each tank (first and second gauge tanks 6 and 7) (charging step). The time required for this charging step is called the charging time.
[0015]
After the end of the charging step, the first and second electromagnetic three-way valves 8 and 9 are operated to shut off the compressed air supply device 2 and the first and second gauge tanks 6 and 7 (performed in the charging step). The state in which the hollow portion 15 of the work 16 is cut off from the first passage 4 and the master tank 20 is cut off from the second passage 5 is continued.) The differential pressure between the tanks 6 and 7 is confirmed (differential pressure confirmation step). At this time, since compressed air is supplied to the first and second gauge tanks 6 and 7 for a certain period of time and the first and second gauge tanks 6 and 7 have the same volume, the first and second gauges described above are used. Due to the filling of the tanks 6 and 7 with the compressed air, the differential pressure sensor 10 indicates "zero".
[0016]
Next, the controller 32 receives the signal indicating “zero” from the differential pressure sensor 10 and switches and operates the airtightness confirmation side valve 26, and the compressed air supply device 2 and the main tube 14 (therefore, the hollow portion 15 of the work 16). And an airtight inspection is performed (airtightness inspection step).
At this time, if there is a gap in the measurement nozzle 12 or the work 16 due to breakage of the measurement nozzle 12 or the work 16 or defective mounting (mounting posture) of the measurement nozzle 12 or the like, and compressed air leaks, the main tube side pressure sensor The pressure value detected by 23 does not reach the set pressure of the airtightness confirmation side regulator 25. When the detected pressure value of the main tube side pressure sensor 23 does not reach the set pressure value even after a certain period of time has elapsed, the controller 32 displays an abnormal alarm (poor airtightness) indicating this on a display (not shown). (Ie, announce). In the present embodiment, the airtightness of the hollow portion 15 of the work 16 can be reliably confirmed by performing the airtightness inspection process as described above.
[0017]
In the related art, even if compressed air leaks due to damage of the measurement nozzle 12 or the like or defective mounting (mounting posture) of the measurement nozzle 12, the volume measurement is performed, but the measurement conditions are not satisfied. It is necessary to perform volume measurement (re-measurement) again after remedying the defective state, which results in a time loss and lowers productivity. On the other hand, in the present embodiment, when air is leaking due to the damage of the measurement nozzle 12 or the like or the improper installation of the measurement nozzle 12, an abnormal alarm is displayed on the display, and the measurement conditions are set. The operator can be notified that there is no measurement, so that re-measurement can be avoided and productivity can be improved.
[0018]
On the other hand, when no compressed air leaks from the measurement nozzle 12 or the work 16 in the airtightness inspection step, the pressure detected by the main tube side pressure sensor 23 reaches the set pressure value of the airtightness confirmation side regulator 25. Then, the controller 32 inputs the detection signal of the main tube side pressure sensor 23 that has reached the set pressure value of the airtightness confirmation side regulator 25, operates the airtightness confirmation side valve 26, and connects the airtightness confirmation side tube 24 to the atmosphere. Then, the compressed air in the hollow portion 15 of the work 16 is released to the atmosphere.
[0019]
Subsequently, when a time measured by a timer (not shown) reaches a predetermined time, the controller 32 switches and operates the airtightness confirmation side valve 26 to shut off the main tube 14 and the compressed air supply device 2, and to perform the first and second operations. (2) By operating the three-way solenoid valves 8 and 9, the first gauge tank 6 and the hollow portion 15 of the work 16 are communicated, and the second gauge tank 7 and the master tank 20 are communicated (measurement step). Then, a portion where the hollow portion 15 of the work 16 is fitted to the measurement side container portion 40 by the differential pressure sensor 10 (corresponding to the work side portion 30. Strictly speaking, the work side portion 30 18 is smaller than the work-side part 30, but is hereinafter referred to as the work-side part 30 for convenience, the second gauge tank 7, the master tank 20, and a passage part connecting both of them. A pressure difference between the combined portion (part of the second passage 5) (the master tank side portion 31) is detected (measuring step). As described above, the measurement-side container unit 40 includes the first gauge tank 6, the first electromagnetic three-way valve 8, the passage member 13, and the passage connecting the first gauge tank 6 and the first electromagnetic three-way valve 8. .
In the present embodiment, the display of the abnormal alarm or the start of the measurement process is selectively performed (the selection process is performed) based on the inspection result of the airtightness inspection process (presence or absence of compressed air leakage). .
[0020]
As described above, in a state where the oil 18 is stored in the hollow portion 15 of the work 16, there is a difference between the volume of the work side portion 30 (the state where the oil 18 is stored) and the volume of the master tank side portion 31. On the other hand, the work-side portion 30 and the master tank-side portion 31 in a state where the oil 18 is not stored have substantially the same volume, and the respective compressions stored in the first and second gauge tanks 6 and 7 having the same volume at the same pressure. Since the air is sealed in the work-side part 30 (the state in which the oil 18 is stored) and the master tank-side part 31, the volume difference between the work-side part 30 and the master tank-side part 31 is expressed as a pressure difference, and The difference and the volume difference show a proportional relationship.
Then, as described above, since a volume difference occurs between the volume of the work side portion 30 (the state where the oil 18 is stored) and the volume of the master tank side portion 31, the differential pressure sensor 10 detects a pressure difference corresponding to the volume difference. Then, the detection signal is output to the controller 32.
The controller 32 obtains a volume difference between the work side portion 30 and the master tank side portion 31 from a signal indicating a pressure difference from the differential pressure sensor 10. Then, the volume difference determined by the controller 32 is displayed on a display (not shown) as the liquid level of the oil 18 (measurement step). Note that the volume of the space 19 is measured by subtracting the volume difference (the storage amount of the oil 18) from the volume of the hollow portion 15 of the work 16.
[0021]
If the liquid level of the oil 18 displayed on the display is within the allowable range, the measuring nozzle 12 is removed from the opening 17 of the work 16 and attached to the opening 17 of the work 16 to be inspected next. An inspection for the work 16 is performed.
When the liquid level of the oil 18 is out of the allowable range, that is, when the liquid level is excessive or insufficient, the measurement nozzle 12 is removed from the opening 17 of the work 16 and the oil 18 is withdrawn or supplied. The liquid level of the oil 18 is adjusted to be within an allowable range.
[0022]
In this embodiment, the case where the volume of the master tank 20 and the volume of the hollow portion 15 of the work 16 are set to be equal to each other is exemplified. In this case, in a state where the oil 18 is not stored in the hollow portion 15 of the work 16, based on the pressure difference detected by the differential pressure sensor 10, the work-side portion 30 and the master tank The volume of the hollow portion 15 of the work 16 can be measured from the volume difference from the portion 31.
[0023]
In the first embodiment, an example in which the electromagnetic airtight confirmation side valve 26 is used as the airtightness confirmation side valve, but a manually operated airtightness confirmation side valve may be used instead. Good.
In the first embodiment, the case where the other end of the airtightness confirmation side tube 24 is connected to the compressed air supply passage 3 is described as an example. Instead, as shown in FIG. (A 2nd embodiment). Further, in the first embodiment, the case where the main tube side pressure sensor 23 is connected to the main tube 14 is described as an example. You may make it connect.
[0024]
【The invention's effect】
According to the first or second aspect of the present invention, the airtightness of the passage member and the work is checked by the airtightness check circuit, so that the compressed air leaks and the work space is not properly measured. Volume measurement can be grasped prior to the measurement. Therefore, re-measurement can be avoided, and the productivity can be improved.
According to the third or fourth aspect of the present invention, the airtightness inspection step of inspecting the airtightness of the passage member and the work is performed prior to the measurement of the volume of the space of the work, so that the measurement conditions are not set. Volume measurement in the state can be avoided, and the productivity can be improved.
[Brief description of the drawings]
FIG. 1 is a diagram schematically showing a volume measuring device according to a first embodiment of the present invention.
FIG. 2 is a diagram schematically showing a volume measuring device according to a second embodiment of the present invention.
FIG. 3 is a diagram schematically showing an example of a conventional volume measuring device.
[Explanation of symbols]
1A Volume measuring device 12 Measurement nozzle 13 Passage member 14 Main tube 15 Hollow portion 16 Work 17 Opening 19 Space 21 Airtightness check circuit 30 Work side portion 31 Master tank side portion (reference side container portion)
40 Measurement side container

Claims (4)

A reference-side container portion in which the compressed gas is sealed, a measurement-side container portion in which the compressed gas is sealed including a passage member connected to the space of the work in which the liquid is stored in the hollow portion, and the reference-side container portion and A volume measuring device that has a differential pressure detecting unit that detects a pressure difference of the measurement-side container unit, and that measures the volume of the space using the pressure difference,
An airtightness check circuit for checking the airtightness of the passage member and the work is provided. The passage member includes a main tube and a measurement nozzle having one end connected to the main tube, and the measurement nozzle is attached to an opening of the work,
The measurement-side container section includes a measurement-side tank having a predetermined volume for storing a compressed gas, a measurement-side main valve, and the passage member, and the measurement-side main valve is a compressed gas supply source that supplies a compressed gas. For the measurement side tank and the main tube, it is possible to selectively perform mutual communication or blocking,
The airtightness check circuit includes a pressure sensor provided to detect an internal pressure of the main tube, and one end branched and connected to the main tube and the other end connected to the compressed gas supply source to guide the compressed gas. An airtightness confirmation side tube, an airtightness confirmation side regulator provided in the middle of the airtightness confirmation side tube to adjust the pressure value of the compressed gas supplied to the main tube, and a communication with the main tube and the compressed gas supply source; 2. The volume measurement device according to claim 1, further comprising an airtightness check valve capable of shutting off and communicating the main tube to the atmosphere. A reference-side container portion in which the compressed gas is sealed, a measurement-side container portion in which the compressed gas is sealed including a passage member connected to the space of the work in which the liquid is stored in the hollow portion, and the reference-side container portion and And a pressure difference detecting means for detecting a pressure difference of the measurement-side container portion, a volume measurement method for measuring the volume of the space portion using the pressure difference,
A measurement nozzle mounting step of mounting the measurement nozzle of the passage member composed of the main tube and the measurement nozzle to the opening of the work,
An airtightness inspection step of measuring the internal pressure by a pressure sensor connected to the main tube and inspecting the airtightness of the passage member and the work after the measurement nozzle is attached to the opening of the work. A volume measurement method, wherein an inspection step is performed prior to a measurement step of measuring a volume of the space. 4. The volume measurement method according to claim 3, further comprising a selection step of selecting whether to notify a poor airtightness or to start a measurement step based on an inspection result of the airtightness inspection step.

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