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Description  |
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FIELD OF THE INVENTION
The present invention relates to a sensor system for contactless distance
measuring.
BACKGROUND OF THE INVENTION
Such a sensor system is already part of the prior art and contains a sensor
body, a sensor element, arranged at the sensor body for contactlessly
measuring the distance between itself and an object, a control unit, for
supplying a measuring voltage to the sensor element and for evaluating the
measuring voltage for the purpose of determining the distance, and a
cable, between the sensor body and the control unit, which is used for
transmitting the measuring voltage.
The sensor system is capable of measuring the distance between the sensor
element and the object, for example, by capacitive or inductive means, if
it is a metallic object, or by optical or acoustical means depending on
the system configuration.
If the sensor body of the sensor system is permanently joined to a tool, it
is possible to position the tool relative to the object or workpiece in
order to be able to machine the workpiece in a suitable manner.
Positioning occurs via a control device which receives the measured
distance as an actual value and controls the position of the sensor body
or the tool by comparing the actual value with a predetermined set tip.
The tool can be, for example, a laser cutting unit for generating a laser
beam by means of which the workpiece can be cut or otherwise treated.
At the beginning of the development of sensor systems of this type, not
only the sensor element but also a large proportion of the sensor
electronics were located inside the sensor body. If, therefore, the sensor
body was separated from the control unit by detaching the cable, the
control unit was able to detect this unambiguously. In such a case, it
generated a warning signal, by means of which the control device for
positioning the sensor body was deactivated or stopped.
Integrating the sensor electronics in the sensor body, however, entailed a
number of disadvantages. Thus, there was only little space inside the
sensor body for installing the electronic components. Installing and
calibrating these electronic components was therefore very time-consuming
and thus represented a considerable cost factor. Due to the space required
for installing the electronic components, the design of the nozzle body
was much more elaborate, which also entailed additional costs.
Furthermore, integrating the electronic components in the sensor body
constituted an obstacle to making the sensor body as slender as possible,
which is required, in particular, when the workpiece or object is to be
machined three-dimensionally under restricted spatial conditions. There is
also the risk of a temperature drift of the actual value or measurement
value supplied by the sensor body due to the sensor electronics heating up
too much inside the sensor body which is subject to very great heating
when it operates in conjunction with a laser cutting tool and is
positioned in the immediate vicinity of the cutting track.
Due to the above disadvantages, the decision was made to arrange the
complete sensor electronics at a very great distance from the sensor body.
More accurately, the sensor electronics were connected to the sensor body
by means of a cable several meters in length, which could also be
shielded. The shielding could also be carried out actively, which means
that the measurement signal present at the sensor element is applied to
the shielding via a capacitor and an amplifier having a gain of V which is
equal to 1.
If the sensor electronics are now separated from the sensor body by
detaching the cable, however, this leads to a misinterpretation of the
actual value by the control unit. In such a case, the control unit detects
a very large actual value or distance which is much greater than the
normal operating distance, so that it attempts to reduce this distance
again. This involves the considerable risk that the sensor element and the
sensor body run against the object or workpiece, which could lead to
damage.
If, for example, this is a capacitively operating sensor system, the
separation of the cable from the sensor body leads to the control unit
detecting only a severely reduced measuring capacitance, since the signal
line of the cable is now free. However, this effect also rises when the
distance between the sensor body of the sensor element and the object or
workpiece is much greater than the normal working distance. For this
reason, it is not possible to generate an unambiguous warning signal from
the measurement signal.
SUMMARY OF THE INVENTION
Accordingly, the present invention is based on the object of developing a
sensor system of the last-mentioned type, in which the complete sensor
electronics are located outside the sensor body, in such a manner that the
control unit can unambiguously detect whether it is separated from the
sensor body or not.
Pursuant to this object, and others which will become apparent hereafter,
one aspect of the present invention resides in the sensor system having an
identification resistor attached to the sensor body. The identification
resistor is connected to the cable, and the control unit is constructed so
that it supplies an interrogation voltage, which does not influence the
measuring voltage, via the cable to the identification resistor for
interrogating the resistance value of the identification resistor.
It is possible to determine whether or not the identification resistor,
which has a known value, and thus the sensor body, is connected to the
control unit by monitoring the magnitude of the interrogation current
belonging to the interrogation voltage. Thus, an alarm signal can be
generated in a simple manner when, for example, the sensor body and the
control unit are separated from one another and no interrogation current
flows, in order to avoid a mispositioning of the sensor body or sensor
element relative to the object or workpiece.
The control unit can also generate the alarm signal when an interrogated
resistance value of the identification resistor does not correspond to a
predetermined resistance value or deviates from the latter by a
predetermined or threshold value. The interrogated resistance value is
calculated from interrogation voltage and interrogation current, and a
microprocessor can be used for this purpose. The comparison between the
interrogated resistance value and the predetermined resistance value or
predetermined threshold is effected by correspondingly existing
comparators or by software measures with the aid of a microcomputer.
If an identification resistor with a different resistance value is
allocated to each type of sensor body, a sensor identification can be
carried out on the basis of the absolute value of the interrogation
current. For this purpose, there is a comparator for comparing an
interrogated resistance value (current) of the identification resistor
with one or more predetermined resistance values (currents). Thus, the
interrogated resistance value (current) is compared with the predetermined
resistance values (currents) until an appropriate resistance value
(current) is found among the predetermined resistance values (currents).
According to a further embodiment of the invention, the control device is
constructed in such a manner that it interrogates the resistance value or
current of the identification resistor before measuring the distance, or
continuously or intermittently during such a measurement. This ensures
that no mispositionings between the sensor body or workpiece and object
occur during the entire measuring cycle if the cable connection between
the sensor body and the control unit should become detached for whatever
reason.
According to yet another embodiment of the invention, an alternating
voltage is used as the measuring voltage and a direct voltage as the
interrogation voltage. Alternating measuring voltages occur, for example,
in capacitive and inductive sensor systems, whereas a direct voltage is
advantageous as the interrogation voltage, since it can be easily measured
for detecting the state of the connection between control unit and sensor
body.
According to still another embodiment of the invention, the direct voltage
and the alternating measuring voltage are transmitted via the same center
conductor of a coaxial cable, the identification resistor being connected
between the center conductor and the shielding of the coaxial cable. Thus,
only a single cable with two conductors is needed for transmitting the
measuring voltage and the interrogation voltage, which cable would also
have to be used when transmitting the measuring voltage alone. Thus, no
additional wires or possibly other cables are needed to transmitting the
interrogation voltage.
This embodiment can be used, for example, in capacitive or inductive sensor
systems. In this arrangement, the identification resistor has no influence
on the distance measurement value. For example, the measuring capacitance
in a capacitive sensor system would be between the center conductor or the
core of the coaxial cable and earth (workpiece), whereas the
identification resistor is located between the center conductor and the
shield of the coaxial cable. Where active shielding is used, the same
potential is present at the shield conductor and center conductor so that
no current flows through the identification resistor if a correct
connection exists between control unit and the sensor body. The direct
voltage or interrogation voltage has no influence on the distance
measurement value either, since it is only generated from the alternating
measuring voltage, for example by using filters and the like. In an
inductive sensor system, the identification resistor is connected in
series with the sensor element or with the coil arrangement.
In accordance with another embodiment of the invention, the cable between
the control unit and the sensor body is a triaxial cable, the alternating
measuring voltage being transmitted via the cable core and the
identification resistor being connected between the two shields of the
triaxial cable.
According to a very advantageous further embodiment of the invention, the
identification resistor is arranged in a socket which is attached to the
sensor body and to which the cable can be connected via a plug. This type
of integration of the identification resistor clearly facilitates the
assembly of the sensor body, since the identification resistor can already
be connected to the connector socket before it is inserted into the sensor
body. Since the connector socket is permanently connected to the sensor
body, the identification resistor is thus also attached to the sensor
body. Where an inductive sensor system is used, the identification
resistor can be arranged in the connector socket in such a manner that it
is located electrically in series between two center conductor ends of the
connector socket. The insulator then also accommodates the identification
resistor.
A micro-metal film resistor (micromelf resistor) is preferably used as the
identification resistor, which has particularly small dimensions and can
therefore be integrated in the connector socket in a very simple manner.
As already mentioned, the sensor system can operate capacitively, so that
the sensor element is a capacitive element and virtually represents one
electrode of a capacitor, the other electrode of which is formed by the
object or workpiece.
However, the sensor system can also operate inductively, so that the sensor
element is an inductive element. For example, an induction coil or a group
of induction coils can be used as the inductive element, the inductance of
which is changed as a function of the distance from the object or
workpiece.
The respective measurement signals contain information on the change in
capacitance or inductance so that the control unit can determine the
distance of the sensor body or of the sensor element from the object or
workpiece on the basis of this information.
The novel features which are considered as characteristic for the invention
are set forth in particular in the appended claims. The invention itself,
however, both as to its construction and its method of operation, together
with additional objects and advantages thereof, will be best understood
from the following description of specific embodiments when read in
connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
In the Drawings:
FIG. 1 shows a basic circuit diagram of a capacitively operating sensor
system pursuant to the present invention with a coaxial cable between
sensor body and control unit;
FIG. 2 shows a circuit which corresponds to the circuit diagram of FIG. 1
with which an interrogating d.c. voltage and a measurement alternating
voltage can be transmitted via one and the same conductor; and
FIG. 3 shows a sensor body for capacitive distance measuring, shown
partially as an axial section.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The sensor system shown in FIG. 1, which operates capacitively, contains a
sensor body 1, at the tip of which a sensor element 2 is arranged. The
sensor element 2 consists of electrically conductive material, for example
of copper, and is electrically insulated from the sensor body 1. A
workpiece has the reference symbol 3 and is connected to earth potential.
The sensor element 2 and the workpiece 3 thus form a capacitor, the
capacitance of which is a measure of the distance between the two elements
2 and 3.
A coaxial connector socket 4 is located in a side wall of the sensor body 1
and is electrically insulated from the latter. A coaxial plug, not shown,
which is connected to one end of a coaxial cable 5, the other end of which
is connected to a control unit 6, can be connected from the outside to the
coaxial connector socket 4. The center conductor (core) of the coaxial
cable 5 carries the reference symbol 7, while the shielding of the coaxial
cable 5 carries the reference symbol 8. The shielding 8 is connected, for
example, to earth potential.
The coaxial connector socket 4 exhibits a center conductor 9, with respect
to which an outer ring conductor 10 is coaxially arranged. Between the
center conductor 9 and the outer ring conductor 10 an insulating material
11 is located. The outer ring conductor 10 is electrically in contact with
the sensor body 1.
At the output end, the center conductor 9 can be connected via the coaxial
plug, not shown, to the core 7 and the outer ring conductor 10 can be
connected to the shield 8 of the coaxial cable 5.
On the other hand, the center conductor 9 is electrically connected to the
sensor element 2 via a shielded line 12 in the interior of the sensor body
1. The center conductor 9 is electrically connected to the outer ring
conductor 10 of the coaxial connector socket 4 via an identification
resistor 13, also in the interior of the sensor body 1. The identification
resistor 13 exhibits a known or defined resistance value which changes
only very slightly in the temperature range in question of the sensor body
1 and thus is to be considered virtually constant.
To measure the distance between the sensor element 2 and the workpiece 3,
an alternating measurement signal, which is evaluated in a conventional
manner, is transmitted from the control unit 6 via the center conductor 7
of the coaxial cable 5, the center conductor 9 and the shielded line 12 to
the sensor element 2. For example, if it has a fixed frequency, its
amplitude can be used for distance determination.
In addition, the control unit applies a direct voltage as an interrogation
voltage to the identification resistor 13 via the center conductor 7 of
the coaxial cable 5 and the center conductor 9 in order to determine, by
measuring the resistance value of this identification resistor 13, whether
the control unit 6 is connected to the sensor body 1 via the coaxial cable
5.
As already mentioned initially, the direct voltage and the alternating
measurement signal do not mutually influence one another, since the
measuring capacitance is located between the center conductor 7 or the
center conductor 9 and earth or the workpiece 3, whereas the
identification resistor is located between the center conductor 7 or the
center conductor 9 and the shield 8 or the outer ring conductor 10. Since
the distance measurement value is only generated from the alternating
measuring voltage which can be filtered appropriately, it is not
influenced by the direct voltage or interrogation voltage present on the
center conductor 7.
If the control unit 6 is electrically separated from the sensor body 1
because, for example, the coaxial plug, not shown, has been detached from
the coaxial connector socket 4, no direct current flows via the center
conductor 7 to the shield 8 because of the direct or interrogation voltage
applied to the center conductor 7. The control unit 6 detects this
condition by measuring the direct current and generates an alarm signal
which deactivates or stops the control device for positioning the sensor
body 1 relative to the workpiece 3. The sensor body 1 can thus not be
mistakenly driven against the workpiece 3.
If, in contrast, the control unit 6 and the sensor body 1 are electrically
connected to one another via the coaxial cable 5, a direct current flows
from the center conductor 7 to the shield 8, in accordance with the
resistance value of the identification resistor 13 due to the
interrogation voltage applied to the center conductor 7, so that the
control unit 6 does not generate a warning signal in this case and, in
addition, can recognize the type of sensor body 1 by means of the measured
direct current value. Depending on the sensor body type, an identification
resistor 13 having a different resistance value can be used. For example,
a suitable control program for positioning the sensor body 1 relative to
the workpiece 3 can then be selected independently of the type of sensor
body 1.
With reference to FIG. 1, the sensor body 1 is connected with the control
unit 6 via a coaxial cable 5 which, however, can also be a shielded cable.
Both the sensor element 2 and the characteristic resistor 13 are connected
with the center conductor 7. The characteristic resistor 13 is located
between the center conductor 7 and the shield conductor 8 of the cable 5.
It is important to the invention that both the measurement voltage for the
capacitive distance measurement and the interrogating voltage for the
characteristic resistor 13 are transmitted via the same center conductor
7. The measurement voltage is an alternating voltage, while the
interrogating voltage is a d.c. voltage which is superimposed on the
alternating voltage.
Another very important feature in FIG. 1 consists in that the shield
conductor 8 of the cable 5 is connected to an active shield potential. The
active shield potential is obtained in that the measurement voltage,
connected to the center conductor 7, is guided to the shield conductor 8
via an amplifier having an amplification factor of V which is greater than
or equal to 1. Thus, the alternating measurement voltage has the same
phase at the center conductor 7 and at the shield conductor 8 so that no
a.c. current passes through the interrogating resistor 13. Rather, only
the capacitive distance measurement is carried out with the aid of the
alternating voltage, wherein the alternating voltage reaches the sensor
element 2 via the conductor 12.
It should be pointed out that no alternating current passes through the
interrogating resistor 13 due to the active shielding. Rather, the
interrogating resistor 13 is supplied with a d.c. voltage so that an
interrogating current d.c. voltage passes through the resistor 13. The
interrogating current d.c. current, however, does not pass through the
sensor element 2 since the sensor element 2 is separated from the
workpiece 3.
Therefore, the substantial characteristic features of the present invention
consist of the features that the characteristic resistor 13 and the sensor
electrode 2 are connected with the same center conductor 7; an alternating
measurement voltage as well as an interrogating d.c. voltage are
transmitted via the center conductor 7; and an active shield potential is
connected to the shield conductor 8 of the cable 5.
The identification resistor 13, is preferably a micro-metal film resistor
which is very small and can therefore be integrated directly in the
interior of the connector socket.
FIG. 2 illustrates another circuit with which the interrogating d.c.
voltage and the measurement alternating voltage can be transmitted via one
and the same conductor. The circuit corresponds to that shown in FIG. 1.
An a.c. source 100 whose output is connected with the conductor 7 serves
to generate the alternating measurement voltage. The alternating
measurement voltage accordingly reaches the sensor element 2 via conductor
7 and conductor 12. It is altered by the capacitance C.sub.measurement so
that a measurement signal is located at the (+) input of the amplifier
101. The output of the amplifier 101 is guided to a rectifier 102 with a
low-pass filter via a decoupling capacitor (filter capacitor) C. The
distance signal U.sub.distance can be taken off at the output of the
latter.
The amplifier 101 has an amplification factor V which is greater than or
equal to 1 and the output of the amplifier 101 is likewise guided to the
shield conductor 8 via the decoupling capacitor C to supply the shield
conductor 8 with active shield potential in this way. It is also important
to note that it is possible for the amplification factor V of the
amplifier 101 to be less than 1. An amplification factor of slightly less
than 1, such as, for example, 0.95 is also envisioned and is possible with
the circuitry of the present invention.
The interrogating d.c. voltage for the characteristic resistance 13 is
generated by means of a d.c. voltage source 103 and given to the center
conductor 7 via a resistor 104 and a coil 105. The coil 105 serves to
block alternating currents and is connected in series with the resistor
104. The coil may be omitted in case of a high stability of the d.c.
voltage generated by the d.c. voltage source 103. In other words, the
interrogating d.c. current from the d.c. current source 103 passes through
the elements 104 and 105 to the center conductor 7 and through the
characteristic resistor 13 and the shield conductor 8 back to a line
between the decoupling capacitor C and the input of the rectifier 102. A
coil 106 connected to the output of the amplifier 101 serves to block
alternating currents. The other end of the coil 106 is connected with an
output 107 at which the characteristic voltage V.sub.characteristic can be
taken off, specifically via a resistor 108. An RC low-pass filter can be
used instead of the elements 106, 108.
Thus, the characteristic features of the invention are also realized in
this case, the alternating voltage from the a.c. source 100 and the d.c.
voltage from the d.c. source 103 being supplied to the same conductor,
namely the center conductor 7 of the shielded cable. Its shielding 8
receives active sensor potential, specifically from the output of the
amplifier 101 via the decoupling capacitor C, so that both conductors 7
and 8 are connected to the same alternating potential. Accordingly, no
alternating current can pass through the resistor 13. Only the
interrogating current d.c. which produced a corresponding voltage drop at
the resistor 108 passes through this resistor 13. The voltage at the
output 107 can then be compared in a known manner with other voltage
values in order thereby to determine the magnitude of the resistance 13
when the magnitude of the interrogating current of the current source 103
is known.
FIG. 3 shows such a case by means of the example of a capacitive sensor
body.
The sensor body 1 contains a sensor element 2 which consists of
electrically conductive material and has a nozzle 14 at the tip. The
nozzle 14 contains a front area 15 of electrically conductive material
which is in electrical contact with the sensor element 2. However, the
front area 15 is electrically insulated from the remaining area 16 of the
nozzle 14, for example, by a suitable ceramic adhesive by means of which
the parts 15 and 16 are permanently joined to one another. The area 16
also consists of electrically conductive material and has a shielding
function. An electrically conductive sleeve 17 concentrically surrounds
the nozzle and is connected to it. A cap nut 18 of electrically conductive
material, which encircles a flange 2a of the sensor element 2 and can be
screwed into the sleeve 17 is used for holding the sensor element 2 on the
tip of the front area 15. The cap nut 18 is electrically insulated in the
area where it is connected to the sensor element 2 or the outer flange 2a,
so that the sensor element 2 and the cap nut 18 do not have any electrical
contact with one another. In contrast, the cap nut 18 is electrically
connected to the sleeve 17 and, via the latter, electrically connected to
the area 16 of the nozzle 14.
In the side area of the sleeve 17, the coaxial connector socket 4 is
screwed in, to which the coaxial cable 5 of FIG. 1 can be connected via
the coaxial plug, not shown. The outer ring conductor 10 of the coaxial
connector socket 4 is in electrical contact with the sleeve 17 and is at
shield potential. The shield potential is either earth potential or, in
the case of active shielding, the measuring potential. The center
conductor 9 of the coaxial connector socket 4 is electrically insulated
from the outer ring conductor 10 by means of an insulator 11, the center
conductor 9 being electrically connected to the front area 15 of the
nozzle 14 via a shielded line 12 in the interior of the sensor body 1. The
alternating measurement signal supplied by the control unit 6 thus passes
via the center conductor 9 and the shielded line 12 to the front area 15
and from there to the sensor element 2. The elements 16, 17 and 18 are
also used as shielding elements.
As can be seen in FIG. 3, an identification resistor 13 is located in the
interior of the hollow-cylindrically constructed outer ring conductor 10
and is thus protected against damage. One terminal of the identification
resistor 13 is connected to the center conductor 9, while the other
terminal of the identification resistor 13 is connected to the outer ring
conductor 10. The identification resistor 13 can be integrated in the
coaxial connector socket 4 even before the latter is screwed into the
sleeve 17. If, in contrast, the insulator 11 completely fills the
remaining hollow space inside the outer ring conductor 10, the
identification resistor 13 can come to be located, instead of in the
interior of the outer ring conductor 10, also at its front end and on the
insulator 11. In other respects, the mode of operation of the
identification resistor 13 in FIG. 3 corresponds to the mode of operation
of the identification resistor 13 in FIG. 1.
While the invention has been illustrated and described as embodied in a
sensor system for contactless distance measuring, it is not intended to be
limited to the details shown, since various modifications and structural
changes may be made without departing in any way from the spirit of the
present invention. Without further analysis, the foregoing will so fully
reveal the gist of the present invention that others can, by applying
current knowledge, readily adapt it for various applications without
omitting features that, from the standpoint of the prior art, fairly
constitute essential characteristics of the generic or specific aspects of
this invention. What is claimed as new and desired to be protected by
Letters Patent is set forth in the appended claims.
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