Device for measuring residual voltage and energy in a piece of equipment

A device is provided for measuring the voltage and energy between the contacts of a male connector from a piece of electronic equipment after it has been disconnected for a given period of time from a source of AC power. The device has both a voltage meter and a milli-joules meter which are connected into any one of a series of four circuits. In the first circuit, the meters are connected across the high voltage contact and the low voltage contact of the male connector. In the second circuit, the meters are connected across the high voltage contact and the safety ground, in the third circuit the meters are connected across the low voltage contact and the safety ground, and in the fourth circuit the meters measure the residual voltage and energy between the tip of a conductive probe and safety ground. A control element controls a relay to connect or disconnect the meters into the circuit selected after the piece of equipment being tested has been disconnected from a source of power for a given period of time.

The present invention relates to a device for measuring the residual 
voltage and energy across the contacts of a piece of equipment after it 
has been disconnected from a source of AC power. 
BACKGROUND OF THE INVENTION 
The medical industry employs numerous pieces of complex electronic 
equipment which must be operated safely so as not to cause injury to the 
technicians operating the equipment or to patients with whom it is brought 
into contact. The International Electro-Technical Commission (IEC) has 
been formed to establish uniform standards for testing such equipment 
throughout the European countries, and U.S. manufacturers of electronic 
equipment for the medical industry who want to sell their products in the 
European market must determine whether their equipment meets the safety 
standards as established by the IEC. The IEC 601-1 Universal Medical 
Equipment Safety Standards, which have recently issued, are currently 
being adopted by all developed countries of the world, and manufacturers 
of electronic equipment for the medical industry are in need of a device 
to carry out certain of the new tests required by these standards. 
The new Medical Equipment Safety Testing Standards (IEC Standards) require, 
among other things, that the voltage between the various connector pins of 
a male connector for an electronic piece of equipment have a voltage which 
does not exceed 60 volts when measured one second after being disconnected 
from a source of AC current the test conducted with an instrument, the 
internal impedance of which does not affect the test. The standard 
requires that the test be performed 10 times with a voltage across the 
connector pins not exceeding 60 volts during any of the 10 measurements. 
Measurements are to be taken across the high voltage and low voltage pins, 
across the high voltage and ground pins and across the low voltage and 
ground pins. 
The standards further provide that in the event more than 60 volts remain 
across any of the pins of a piece of equipment one second after it is 
disconnected from a source of AC power, the energy stored within the 
device should be tested by a measurement across the connector pins taken 
one second after the device is disconnected from a source of AC power, and 
the stored energy should be less than 2 milli-joules. 
The standards also require that live capacitors of a circuit which become 
accessible after an access cover has been removed shall not have a 
residual voltage exceeding 60 volts, or if this value is exceeded, not 
have a residual energy of 2 milli-joules. 
Presently, there is no equipment available to undertake the tests to 
determine whether the standards set by the IEC for a piece of equipment 
have been met, and manufacturers are manually connecting the appropriate 
meters across connector pins to determine whether their equipment will 
meet the standards of the IEC. Therefore, it would be desirable to provide 
a device capable of measuring the residual voltage and power across the 
contacts of a piece of equipment after it has been disconnected from a 
source of AC power in order that it may determine if the device complies 
with the standards as set by the IEC. 
SUMMARY OF THE INVENTION 
Briefly, the present invention is embodied in a device for measuring the 
voltage and energy between the contacts of a male connector from a piece 
of electronic equipment after it has been disconnected for a given period 
of time from a source of AC power, where the connector has a high voltage 
contact and a low voltage contact. The device has a female connector for 
receiving a male connector having a high voltage contact and a low voltage 
contact from a piece of equipment to be tested and has a plug or connector 
for attaching the device to a source of AC power. A first switch 
selectively connects and disconnects the high voltage contact of the 
female connector to the high voltage contact of the plug for receiving AC 
power, thereby connecting or disconnecting the piece of equipment plugged 
into the female connector of the device to a source of AC power. 
In a preferred embodiment, the device has both a voltage meter and a 
milli-joules meter which are connected into any one of a series of four 
circuits. In the first circuit, the meters are connected across the high 
voltage contact and the low voltage contact of the female connector. In 
the second circuit, the meters are connected across the high voltage 
contact in the safety ground of the female connector. In the third 
circuit, the meters are connected across the low voltage contact and the 
safety ground, and in the fourth circuit, the meters are connected to 
measure the voltage and energy difference between the tip of a conductive 
probe and safety ground. A relay selectively connects and disconnects the 
meters into the circuit selected by the second switch. 
The device further has a control element, which may be a microprocessor, 
and includes a timing device. The control element is responsive to the 
actuation of the first switch and is connected to the relay for switching 
the relay to connect or disconnect the meters into the circuit selected by 
the second switch after the first switch has disconnected the high voltage 
contact of the female connector from a source of power for a given period 
of time. 
In the preferred embodiment, the first switch is actuated by the control 
element, and the control element also has a detector for determining when 
peak voltage is being applied to the high voltage contact of the female 
connector. The control element actuates the first switch to disconnect the 
high voltage contact of the female connector from the source of electrical 
energy when the AC voltage is at a peak. The control element will 
thereafter actuate the relay to connect the voltage and milli-joules 
meters into the circuit selected by the second switch after a given period 
of time, as for example, after one second, or such other period of time as 
is determined by the timing element. A third switch is also connected to 
the control element which, when closed, causes the control element to 
initiate the test sequence described above. 
To test a piece of equipment with the device of the present invention, the 
plug or male connector of a piece of equipment to be tested is inserted 
into the female connector of the present invention, and the male connector 
of the test device is inserted into an outlet of AC current. The second 
switch is adjusted to select one of the four circuits. When the third 
switch is closed, the control element will disconnect the application of 
AC power to the female connector and, after one second, the control 
element will actuate the relay to connect the meters into the circuit and 
measure the voltage and residual power across the elements which the 
circuit is configured to test. In testing a piece of equipment, the 
residual voltage and energy should be tested for each of the four circuits 
of the selector switch. 
The IEC standards require that the voltage test be performed 10 times and 
that the voltage across the high voltage and low voltage contacts of the 
connector not exceed 60 volts in any of the 10 tests. Representatives on 
behalf of the IEC have acknowledged that the purpose of performing the 
test 10 times is to obtain the highest readings of voltage and residual 
energy, and I have found that when AC power is repeatedly applied and 
disconnected from such a piece of equipment, such readings can vary widely 
because the energy being applied to a device from a source of AC power, by 
definition, is continually variable. I have also found, however, that the 
highest readings of residual voltage and energy occur when the tested 
device is disconnected from a source of AC power when the maximum voltage 
is applied across the high voltage and low voltage contacts. 
Representatives of IEC have acknowledged that the standards could be 
modified to accept a single reading from a test device which would measure 
residual voltage and power after the device is disconnected from a source 
of AC power at the instant peak power is applied to the contacts. It is 
believed that the IEC will accept a single test of the piece of equipment 
where the test is administered using a device in accordance with the 
present invention as sufficient to determine whether the device meets the 
IEC medial equipment safety test standards recently adopted.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT 
Referring to FIG. 1, a test device 10 in accordance with the present 
invention has an enclosure 12 and a female AC connector 14 having a high 
voltage contact 16, a low voltage contact 18, and a safety ground contact 
20. The forward surface of the device further has a voltage readout 22, a 
milli-joules readout 24, and a rotatable selector switch 26 having a 
control knob 28 which can be adjusted to any of four settings marked 1, 2, 
3 and 4. The operation of the device is commenced by the pressing of a 
test button 30, and the device is connected by a flexible power line 31 to 
a typical male AC connector 32 having a high voltage contact 34, a low 
voltage contact 36 (shown only in FIG. 2), and a safety ground contact 38 
for connecting the device to a source of AC power. Also extending from the 
enclosure 12 is a second conductive wire 40 terminating in a probe 42 
having an electrically conductive tip 43. 
Referring to FIG. 2, the high voltage contact 34 and low voltage contact 36 
of the male connector 32 are each connected through an electronically 
operated double pole relay 44 to the high voltage contact 16 and the low 
voltage contact 18, respectively, of the female connector 14 with switch 
44A of the relay connecting or disconnecting the high voltage contacts 34, 
16, respectively, and switch 44B connecting or disconnecting the low 
voltage contacts 36, 18, respectively. When the relay 44 is not actuated, 
the switches 44A and 44B are in the closed condition and AC power received 
by the contacts of the male connector 32 is conveyed to the corresponding 
contacts of the female connector 14. 
The voltage across the various contacts is measured by a typical voltage 
measuring circuit 46, the output of which is connected to the voltage 
readout 22, and similarly, the energy output across the various contacts 
is measured by a typical milli-joules measuring circuit 48, the output of 
which is connected to the milli-joules readout 24. The voltage measuring 
circuit 46 is connected or disconnected from the circuit by a second 
double pole electronically operated relay 50, having switches 50A, 50B 
which connect or disconnect the two sides of the voltage measuring circuit 
46 to the center poles of the first and second wipers 26A, 26B, 
respectively, of the rotatable switch 26. Similarly, a third double pole 
electronically operated relay has switches 52A and 52B, respectively, 
which connect or disconnect the two ends of the milli-joules measuring 
circuit 48 to the center poles of wipers 26A and 26B, respectively. When 
the relays 50, 52 are not actuated, the contacts of the switches 50A, 50B, 
52A, 52B are in the opened condition, and the measuring circuits 46, 48 
are disconnected from wipers 26A and 26B. 
The wipers 26A, 26B of the rotatable switch 26 each have four stationary 
contacts numbered 1-4, respectively, which correspond to the positions 
numbers 1 to 4 of the knob 28, and the wipers 26A and 26B are ganged 
together on a common shaft to which the knob 28 is connected for 
simultaneous operation. When the wipers 26A, 26B are in the first 
position, the voltage and milli-joules measuring circuits 46, 48, 
respectively, are connected across the high voltage contact 16 and the low 
voltage contact 18 of the female connector 14. When the wipers 26A, 26B 
are in the second position, the measuring circuits 46, 48 are connected 
across the high voltage contact 16 and the safety ground contact 20 of the 
female connector 14. When the wipers 26A, 26B are in the third position, 
the measuring circuits 46, 48 are connected across the low voltage contact 
18 and the safety ground contact 20 of the female connector 14, and when 
the wipers 26A, 26B are in the fourth position, the measuring circuits 46, 
48 are connected to measure voltage and milli-joules between the 
conductive tip 43 of the probe 42 and the safety ground contact 38 of the 
male connector 32. 
The device 10 further has a suitable control element 54, which may be in 
the form of a microprocessor, which has a first output line 56 for 
actuating the relay 44 and thereby opening the switches 44A, 44B and a 
second output line 58 for actuating the second and third relays 50, 52, 
respectively, and thereby closing the switches 50A, 50B, 52A, 52B. 
Connected to the control element 54 is a timing circuit 60 for measuring a 
predetermined length of time, such as one second. The control element 54 
is also connected by a synchronization line 62 to the high voltage contact 
34 of the male connector 32, and within the control element 54 is a 
maximum voltage determining circuit 64. The function of the control 
element 54 is commenced by a switch 65 which is closed by depressing the 
test initiation button 30. 
Accordingly, when the male connector 32 of the device is inserted into an 
electrical outlet which is a source of AC current and the male connector 
of a piece of equipment to be tested is inserted into the female connector 
16, the AC power applied to the contacts of the male connector 32 is 
applied through the female connector 14 to the device being tested. The 
control element 54 is configured to respond to the closing of the switch 
65 by issuing a signal through output line 56 to the first relay 44 to 
open the switches 44A, 44B when the AC voltage applied to the high voltage 
connector is at a peak thereby disconnecting the high voltage contact and 
low voltage contact of the piece of equipment being tested from the source 
of electrical power. Then, after a delay for the interval of time 
determined by the timing circuit 60, the control element directs a signal 
through output line 58 to the second and third relays 50, 52 to close 
switches 50A, 50B, 52A, 52B and connect the voltage measuring circuit 46 
and milli-joules measuring circuit 48 across the contacts to be tested. 
The outputs from the measuring circuits 46, 48 are then displayed on the 
associated display devices 22, 24, respectively. 
After the test has been conducted with the circuit configured in accordance 
with one of the settings 1, 2, 3 or 4 of the wipers 26A, 26B, the knob 28 
can be rotated to move the wipers 26A, 26B to a second position, and 
thereafter when the button 30 again is depressed again closing switch 65, 
a second test will be conducted. 
The conductive tip 43 of the probe can be used to test the conductive 
portion of the housing of a piece of electronic equipment or test a 
capacitor accessible within the equipment to be tested upon opening the 
enclosure to determine the residual voltage and energy therein. This test 
is conducted by contacting the end of the probe 42 to a contact of a 
capacitor while the wipers 26A, 26B are rotated to the fourth position. It 
should be appreciated that although the control element 54 is described as 
a microprocessor, integrated circuits are available for detecting the peak 
voltage of AC current, and such circuits can be combined with a commonly 
known timing circuit 60 to open switches 44A, 44B of the first relay 44 
when peak power is being applied to the high voltage contact, and to close 
the second and third relays 50, 52 after a given interval of time. A 
microprocessor as previously described would then not be required. 
While the present invention has described in connection with one 
embodiment, it will be understood that many changes and modifications 
thereof may be made without departing from the true spirit and scope of 
the present invention. It is therefore, intended by the appended claims to 
cover all such changes and modifications which come within the true spirit 
and scope of the invention.