Leak test method and apparatus
First Claim
Patent Images
1. A leak test method in which:
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
the pressure difference between said master and said work is measured by a differential pressure sensor;
a pressure difference variation per unit time is calculated from a measured value of said pressure difference;
a drift is subtracted from said pressure difference variation to obtain a leakage; and
said leakage is compared with a leakage reference value to determine if said pressurized gas leaks out from said work;
said method comprising the steps of;
(a) opening a third valve connected between said work and said master to establish a pressure equilibrium therebetween, and then closing said third valve;
(b) measuring a first pressure difference variation per unit time;
(c) opening said third valve, after said step (b), to establish a pressure equilibrium between said master and said work, and then closing said third valve;
(d) measuring a second pressure difference variation per unit time after said step (c), wherein;
said first and second pressure difference variations are measured in a measurement period which is an initial pressure difference variation domain;
(e) obtaining an exponential approximate expression of time from said first and second pressure difference variations; and
(f) calculating a pressure difference variation as a pressure difference stabilization period subtracting said pressure difference variation from said first pressure difference variation to obtain said drift.
1 Assignment
0 Petitions
Accused Products
Abstract
In a leak test method and apparatus which introduces high-pressure gas into a work and a master from a high-pressure gas source through first and second electromagnetic valves, respectively, closes the first and second electromagnetic valves, detects the pressure difference between the work and the master by a differential pressure sensor, and compares the amount of leakage, obtained from the pressure difference, with a leakage reference value to thereby decides the work to be leak-free or leaky, a third electromagnetic valve is provided which permits and inhibits the passage of gas between the work and the master. Prior to measuring pressure difference variations in a measurement period and a stabilization period, the third electromagnetic valve is opened to establish a pressure equilibrium between the work and the master, then the electromagnetic valve is closed, then measures the pressure difference variations, and a last pressure difference variation δpe is subtracted from an initial pressure difference variation δps to obtain the amount of drift.
62 Citations
16 Claims
-
1. A leak test method in which:
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
the pressure difference between said master and said work is measured by a differential pressure sensor;
a pressure difference variation per unit time is calculated from a measured value of said pressure difference;
a drift is subtracted from said pressure difference variation to obtain a leakage; and
said leakage is compared with a leakage reference value to determine if said pressurized gas leaks out from said work;
said method comprising the steps of;(a) opening a third valve connected between said work and said master to establish a pressure equilibrium therebetween, and then closing said third valve;
(b) measuring a first pressure difference variation per unit time;
(c) opening said third valve, after said step (b), to establish a pressure equilibrium between said master and said work, and then closing said third valve;
(d) measuring a second pressure difference variation per unit time after said step (c), wherein;
said first and second pressure difference variations are measured in a measurement period which is an initial pressure difference variation domain;
(e) obtaining an exponential approximate expression of time from said first and second pressure difference variations; and
(f) calculating a pressure difference variation as a pressure difference stabilization period subtracting said pressure difference variation from said first pressure difference variation to obtain said drift. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
(f) making a check to see if the type of work is changed;
(g) if so, executing a drift calculating process by said steps (a) to (e), and writing the resulting drift as an initial drift into a drift table;
(h) if the type of work is not changed, a moving average of latest pieces of drift data stored in said drift table is calculated as an estimated drift;
(i) measuring a third pressure difference variation in a measurement period which is an initial pressure difference variation domain, and calculating the difference between said third pressure difference variation and said estimated drift;
(j) comparing the absolute value of said difference with a leakage reference value, and deciding said work to be leak-free or leaky depending on whether said absolute value is smaller or larger than said reference value; and
(k) writing said third pressure difference variation on said work decided to be leak-free as the latest drift into said drift table.
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
-
8. The method of claim 7, wherein said moving average is obtained by assigning larger weights to said initial drifts obtained by said drift calculating process and subjecting them to weighted averaging.
-
9. The method of claim 7, wherein said third pressure difference variation to be written in said drift table is only one that falls in a range smaller than said leakage reference value.
-
10. The method of claim 7, wherein said calculated initial drift is stored in a memory in correspondence with the type and temperature of a work at that time, and when it is decided that the type of said work is changed, an initial drift corresponding to the type of said work is read out and used.
-
11. The method of claim 1, wherein a drift PD is expressed by the following linear approximate expression of the difference between the temperature TA of said work and the temperature TB of a jig for connecting said work to a conduit:
-
12. A differential pressure type leak test apparatus for testing a work for leaks based on variations in the pressure difference between said work and a master, said apparatus comprising:
-
a high-pressure gas source;
first and second conduits for interconnecting said high-pressure gas source and said work and said master through first and second valves, respectively;
a third valve connected between said first and second conduits, for permitting and inhibiting the passage therethrough of gas between said master and said work;
a differential pressure sensor connected between said first and second conduits, for detecting the pressure difference between said master and said work;
a sequence control part which generates a time sequence for opening, and closing of said first, second and third valves and a time sequence for detecting said pressure difference by said differential pressure sensor in a drift calculating mode and in a leak test mode;
a valve control part placed under the control of said time sequence by said sequence control part, which, in said drift calculating mode, opens said first and second valves to introduce therethrough high-pressure gas into said work and said master from said high-pressure gas source and, prior to measuring first and second pressure difference variations, opens said third valve to establish a pressure equilibrium between said work and said master, and thereafter closes said third valve and which, in said leak test mode, opens said first and second valves to introduce therethrough high-pressure gas into said work and said master from said high-pressure gas source and, prior to measuring a third pressure difference variation, opens said third valve to establish a pressure equilibrium between said work and said master and thereafter closes said third valve;
a drift calculating part placed under sequence control by said sequence control part, which, in said drift calculating mode, executes in said first and second pressure difference variation measurements a process of obtaining first and second pressure difference variations by detecting pressure differences at a first time after the closing of said third valve and at a second time a predetermined time after said first time and calculates a drift from said first and second pressure difference variations;
a leakage calculating part placed under sequence control by said sequence control part, which, in said leak test mode, obtains a third pressure difference variation by detecting pressure differences at the first time after the closing of said third valve and at the second time a predetermined time after said first time and subtracts said drift from said third pressure difference variation to obtain the leakage from said work; and
a pass/fail decision part which compares said leakage with a leakage reference value and decides that said work is leak-free or leaky, depending on whether said leakage is smaller or larger than said leakage reference value. - View Dependent Claims (13, 14)
-
-
15. A leak test method in which:
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
the pressure difference between said master and said work is measured by a differential pressure sensor;
a pressure difference variation per unit time is calculated from a measured value of said pressure difference;
a drift is subtracted from said pressure difference variation to obtain a leakage; and
said leakage is compared with a leakage reference value to determine if said pressurized gas leaks out from said work;
said method comprising the steps of;(a) opening a third valve connected between said work and said master to establish a pressure equilibrium therebetween, and then closing said third valve;
(b) measuring a first pressure difference variation per unit time;
(c) opening said third valve, after said step (b), to establish a pressure equilibrium between said master and said work, and then closing said third valve;
(d) measuring a second pressure difference variation per unit time after said step (c);
(e) calculating said drift from said first and second pressure difference variations checking to see if the type of said work currently under test is different from the type of the previously tested work; and
(f) checking to see if a change in the temperature of said current work is larger than a reference value;
wherein if the result of at least one of said checks is affirmative, a drift calculating process by said steps (a) to (e) is executed; and
if the results of both of said checks are not affirmative, measuring a pressure difference variation of said work under test as a third pressure difference variation in said measurement period, and subtracting said drift from said third pressure difference variation, comparing the absolute value of the result of said subtraction with a leakage reference value, and deciding if the work under test is leaky or leak-free depending upon whether said absolute value is larger or smaller than said leakage reference value.
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
-
16. A leak test method in which:
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
the pressure difference between said master and said work is measured by a differential pressure sensor;
a pressure difference variation per unit time is calculated from a measured value of said pressure difference;
a drift is subtracted from said pressure difference variation to obtain a leakage; and
said leakage is compared with a leakage reference value to determine if said pressurized gas leaks out from said work;
said method comprising the steps of;(a) opening a third valve connected between said work and said master to establish a pressure equilibrium therebetween, and then closing said third valve;
(b) measuring a first pressure difference variation per unit time;
(c) opening said third valve, after said step (b), to establish a pressure equilibrium between said master and said work, and then closing said third valve;
(d) measuring a second pressure difference variation per unit time after said step (c); and
(e) calculating said drift from said first and second pressure difference variations wherein said measurements of said first and second pressure difference variations in said steps (b) and (d) are performed, in said steps (a) and (c), by closing said third valve, then resetting the reading of said first detected pressure difference value at said first time, and obtaining, as said pressure difference variations, said second detected pressure difference value at second time a predetermined time Δ
t after said first time.
- pressurized gas is introduced into a master and a work connected to a high-pressure gas source via first and second valves, respectively;
Specification
-
- Resources
Litigation Campaign Assessment
Thank you for your request. You will receive a custom alert email when the Litigation Campaign Assessment is available.
×
-
Current AssigneeCosmo Instruments Co. Ltd.
-
Original AssigneeCosmo Instruments Co. Ltd.
-
InventorsHorikawa, Hiroshi, Furuse, Akio, Nakagomi, Masayuki
-
Primary Examiner(s)LARKIN, DANIEL SEAN
-
Application NumberUS09/172,866Time in Patent Office845 DaysField of Search73/492, 73/493US Class Current73/49.2CPC Class CodesG01M 3/3263 using a differential pressu...
