The present invention concerns a connection system for connecting a probe to an electronic device in an ultrasound system.
The present invention concerns more precisely a connection system for connecting a probe to an electronic device, wherein the probe emits and/or receives ultrasound waves into a medium, and wherein the connection system comprises:
It is known from the document U.S. Pat. No. 5,882,310 a connection system adapted for a multiport ultrasound imaging system. The imaging system comprises a plurality of receptacles that receives a probe connector, each receptacle having a plate that is actuated by a pressure roller to rotate the receptacle contacts to the probe connector contacts.
Only one receptacle can be activated at the same time, and only one probe is connected to the ultrasound imaging system. The connection system eliminates the need of having switches inside the imaging system to select a specific ultrasound probe. Such connection system is advantageous in terms of size and cost.
However, this connection system is able connect only one connector to the imaging system at the same time. The imaging system needs to be powered to mechanically disconnect and remove a connected probe. The probe cannot be easily and rapidly disconnected and removed from the electronic device.
One object of the present invention is to provide a connection system that also eliminate the switches inside the ultrasound system, and that is improved so as it is possible to easily mechanically connect or disconnect the probe from the ultrasound system.
To this effect, the connection system is characterized in that:
Thanks to these features, the second element can be in a state (locked/released) independent from the position of the third element (activated/inactivated).
The probe can be removed from the ultrasound electronic device, the electrical connection between the first and second element being established or not by the actuation device.
The probe can be removed from the ultrasound electronic device rapidly by a user that manipulates the locking mechanism, without powering the electronic device. For example, the probe can be removed from the system for cleaning.
The probe is electrically connected or not to the ultrasound electronic device by the actuation device, said actuation device being powered and controlled by the electronic device.
An ultrasound electronic device having a plurality of connection systems, as defined above, for connecting a plurality of probes does not need to have switches.
The signal to noise ratio (SNR) of the received signals is also improved.
One or more than one probe can be simultaneously connected to the electronic device.
In various embodiments of the connection system, one and/or other of the following features may optionally be incorporated.
According to an aspect of the connection system, the first electrical contacts are situated according to a contacts plane and the activation device can move the third element according to an activation direction perpendicular to said contacts plane.
According to an aspect of the connection system, the second element is adapted to be inserted into or to be removed from the third element according to an insertion direction so as the locking mechanism can lock or release the second element, and wherein said insertion direction is not parallel to said contact plane.
According to an aspect of the connection system, the insertion direction is parallel to the activation direction.
According to an aspect of the connection system, the third element comprises a connecting shaft extending according said insertion direction through the first element towards the second element, so as the second element can be locked to the third element.
According to an aspect of the connection system, the actuation device is an electric linear actuator that is controlled by the electronic device.
According to an aspect of the connection system, the locking mechanism is a rotatable handle mounted on the second element, said handle being rotated by a user to lock or to release the second element onto the third element.
Another object of the present invention is to provide an ultrasound system comprising:
wherein the electronic device is adapted to control the actuation device to move the third element between the activated position and the inactivated position.
In various embodiments of the ultrasound system, one and/or other of the following features may optionally be incorporated.
According to an aspect of the ultrasound system, the actuation device and the third element are integrated with the first element inside the electronic device.
According to an aspect of the ultrasound system, it comprises a set of at least two connection systems, and the electronic device comprises:
wherein the electronic device can control each one of the activation device of the set for moving each third element of the set between the activated position and the inactivated position.
According to an aspect of the ultrasound system, it comprises a set of at least four connection systems, and the electronic device comprises:
According to an aspect of the ultrasound system, the connection systems are organized according to a matrix arrangement.
According to an aspect of the ultrasound system, it comprises a connection unit comprising:
Other features and advantages of the invention will be apparent from the following detailed description of at least one of its embodiments given by way of non-limiting example, with reference to the accompanying drawings. In the drawings:
The
The electronic device 2 sends excitation signals to the probe 3 via the connection system 10 so as to emit at least an ultrasound wave into a medium 9. The scattering of the wave inside the medium generates backwards reflected ultrasound waves that are sensed by the probe 3 and returned in the form of reflection signals to the electronic device 2 via the connection system 10. Such method applies to ultrasound imaging of the medium as it is well known. The following description will mainly explained in view of imaging application. However, it may be also applied to the treatment application.
The electronic device 2 comprises:
The probe 3 comprises:
The cable 7 is flexible. A user can move the head 6 above an external surface 9a of the medium 9 to get a plurality of images from the ultrasound system, each of said images representing a slice of the inner densities of the medium 9 at the plurality of positions of the head 6 above the external surface 9a.
Therefore, the connection system 10 comprises at least:
When the first and second electrical contacts 11a, 12a are into contact to each other, the first and second electrical contacts transmit electrical signals from the probe 3 to the electronic device 2 and from the electronic device 2 to the probe 3.
The connection system 10 further comprises:
The actuation device 14 may be any type of actuator that is able to move the third element 13 relative to the first element 11 between an activated position and an inactivated position. The actuation device 14 may be an electric linear actuator, an electric rotation actuator, an electric motor, an electric step motor, an electromagnet.
The third element 13 may be suspended relative to the electronic device 2 or first element 11 by an elastic element 17, e.g. a coil spring. The position of the third element 13 without actuation device action can be predetermined.
The actuation device 14 and the third element 13 are preferably integrated inside the electronic device 2 as disclosed in the herein presented embodiments. The electronic device 2 directly controls and powers the actuation device 14, and the second element 12 (probe connector) is compact in size and light. The second element 12 belonging to the probe 3 is therefore not modified compared to the known elements of already available probes. The connection device 10 according to the herein disclosed embodiments allows backward compatibility: Existing probes 3 can be used on an electronic device 2 incorporating said connection systems 10.
The actuation device 14 may be alternatively integrated inside the probe 3.
The second element 12 is linked to the third element 13 as explained in the following description.
In the activated position of the third element 13, the first element 11 is proximal to the second element 12 so as the first electrical contacts 11a can contact the second electrical contacts 12a to established electric continuity.
In the inactivated position of the third element 13, the first element 11 is distant from the second element 12 so as first electrical contacts 11a can not contact the second electrical contacts 12a. For example, the first electrical contacts 11a are at a distance from the second electrical contacts 12a that is higher than 0.5 mm. The above distance is for example a distance between a first contacts plane CP1 defined by the first electrical contacts 11a and a second contact plane CP2 defined by the second electrical contacts 12a, in said inactivated position of the third element 13.
The second element 12 can be removably fixed or locked to the third element 13 by a locking mechanism 15 to mechanically connect, plug, or lock the probe 3 to the electronic device 2. The second element 12 is then in a locked state.
The second element 12 can be released from the third element 13 by the same locking mechanism 15 to mechanically disconnect, unplug or release the probe 3 from the electronic device 2. The second element 12 is then in a released state.
The third element 13 is an element that is intermediate between the first and second elements 11, 12 of the connection system 10. Thanks to this third element 13, the second element 12 from the probe can be mechanically locked on this third element 13 by the locking mechanism 15. Thanks to the actuation device 14, the third element 13 can be moved relative to the first element 11 for electrically connecting or not the second element 12 to the first element 11.
Contrary to prior art connection systems, the connection system 10 of present invention can provide an electrical connection of the probe 3 that is independent from the mechanical locking of the probe 3 to the electronic device 2.
As soon as the probe 3 is removed from the electronic device 2, after being mechanically disconnected from it, the probe 3 is also electrically disconnected from the electronic device 2: The first and second electrical contacts 11a, 12a do not contact each other and the electrical continuity is broken between the electronic device 2 and the probe 3.
The third element 13 of the connection system 10 can be moved by the activation device 14 from the activated position to the inactivated position, or from the inactivated position to the activated position, the second element 12 of the connection system 10 being in any state: the locked state or the released state, i.e. the second element 12 being locked to the third element 13 or being released from the third element 13.
Therefore, the connection system 10 can be in any of the four following working states S1, S2, S3, S4, that correspond to all the possibilities of the third element 13 positions and the second element 12 states.
The second element 12 is switched between the released state and the locked state by the locking mechanism 15. The third element 13 is switched between the inactivated position and the activated position by the activation device 14.
In the working state S1, the third element 13 is in the inactivated position. The first and second electrical contacts 11a, 12a are not electrically connected to each other. The second element 12 is in the released state. The second element 12 can be removed from the third element 13. The probe 3 can be mechanically removed from the electronic device 2. The locking mechanism 15 may be activated by a user to switch from the working state S1 to the working state S2, to lock a probe 3 on the electronic device 2. Additionally, if no probe is present, the processing unit 4 may switch the third element 13 from the inactivated position (working state S1) to the activated position (working state S3). In that case, the third element 13 is moved by the activation device 14 without any probe.
In the working state S2, the second element 12 is now locked on the third element 13, and the probe 3 is locked on the electronic device 2 and can not be directly removed from the third element 13. The locking mechanism 15 must be activated by a user to switch back to the working state S1 and to release the second element 12, i.e. probe 3. Alternatively, the user may interfere with the ultrasound imaging system 1 and the electronic device 2 (processing unit 4) may switch the third element 13 from the inactivated position to the activated position to switch from the working state S2 to the working state S4.
In the working state S3, the third element 13 is in the activated position. The second element 12 is in the released state, and can be removed from the third element 13. The probe 3 can be mechanically removed from the electronic device 2. The locking mechanism 15 may be activated by a user to switch from the working state S3 to the working state S4 to lock the probe 3 on the electronic device 2. Such working state S3 is therefore a state that should be transient, and that should not be a normal use state.
In the working state S4, the second element 12 is locked on the third element 12, and the probe 3 is also locked on the electronic device 2. The locking mechanism 15 must be activated by a user to switch back to the working state S3 (unlocking or releasing of the probe). The processing unit 4 may switch the third element 13 from the activated position to the inactivated position to switch from the working state S4 to the working state S2.
The switch between the working states S2 and S4 correspond to the activation of connection system 10. This electrically connects or not the first electrical contacts 11a with the second electrical contacts 12a. The processing unit 4 can switch the third element 13 from the inactivated position (working state S2) to the activated position (working state S4). In that case, the third element 13 is moved by the activation device 14, the second element 12 of the probe 3 being installed inside the connection system 10. The actuation device 14 is therefore moving (controlling) the first and second electrical contacts 11A, 12a so as they are switch to electrical contacts or not. They are functioning like electrical switches that are usually used for connecting only one particular selected probe in an electronic device 2 having a plurality of probes connected on it.
Thanks to the above four working states, the second element 12 can be locked or released from the third element 13 independently from the position of the third element 13 relative to the first element 11: in the activated or inactivated position. The probe 3 connected to the connection system 10 can be removed from the ultrasound electronic device 2 rapidly by a user.
The activation device 14 is preferably moving the third element 13 according to an activation direction AD that is perpendicular to the first contact plane CP1. The first and second contact planes CP1, CP2 are preferably parallel to each other.
The second element 12 is for example locked or released to the third element 13 according to an insertion direction ID, said insertion direction being not parallel to the first contact plane CP1, and being preferably perpendicular to said first contact plane CP1. The second element 12 is therefore locked or released to the third element according to a direction that is the same as the activation direction AD that moves the third element 13 relative to the first element 11.
The connection system may have the following features: The third element 13 is situated inside the electronic device bellow the first element 11 so as it is directly moved and controlled by the actuation device 14 inside the electronic device 2. The first element 11 is situated at an external surface of a casing of the electronic device so as to cooperate with the second element 12 from the probe 3. The first element 11 comprises a hole, and the third element 13 comprise a connecting shaft 19 extending at least partially through said hole to the outside of the electronic device 2. The connecting shaft 19 can therefore cooperate with the locking mechanism 15 of the probe 3 so as to lock or unlock the second element 12 to the third element 13: The second element 12 is at positioned at a predetermined position relative to the third element 13. The shaft extends according to the insertion direction ID through the hole of the first element 11.
The locking mechanism 15 is capable to fix or lock the second element 12 at said predetermined position (locked state) or to release the second element 12 so as it can be removed from the electronic device 2. The locking mechanism comprises (at a first end in the direction of the electronic device) a nose adapted to cooperate with the connecting shaft 19 for locking or releasing said second element 12.
The locking mechanism 15 may be of any kind. For example, it is a rotatable handle mounted on the second element 12, said handle being rotated by a user to lock or release the second element from the third element 13. The probe 3 can therefore be extracted from the electronic device 2 at any time: The third element 13 being in an activated or inactivated position, and the electronic device 2 being powered or not.
The electronic device 2 may advantageously comprise a plurality of first elements 11 for connecting a plurality of probes. Usually, such electronic device 2 comprises inner electrical switches to select simultaneously only one probe. The patent U.S. Pat. No. 4,726,230 discloses an example of such electronic device.
The actuation device 14 in present invention replaces the electrical switches included inside the above prior art imaging system. In case of a connection system having lots of electrical contacts (for probes having lots of transducers elements), this is really advantageous: For example, in case of a probe head 6 having a number of 500 transducers elements, such prior art electronic device must incorporate the same number of electrical switches for each one connection system, i.e. for each probe slot (receptacle) of the electronic device. Such architecture leads to an enormous number of electrical switches that use electronic board area and that are costly.
By using the connection system 10 as a switch for all the electrical contacts or wires from a probe, the need for all these switches is eliminated. The document U.S. Pat. No. 5,882,310 discloses an electronic device that comprises such controlled connection system, but this system permits to electrically connect simultaneously only one probe to the electronic device 2. When electrically connected, such connection system is also mechanically locked, and the probe can not be easily unplugged from the electronic device. Such connection system can only work in the above defined working states S1 and S4, and can not work in the working states S2 and S3.
The connection system 10 according to the invention therefore differs in that the electrical connection of the probe 3 to the electronic device 2 is independent from the mechanical locking of the probe 3 to said electronic device 2.
The actuation device 14 of present invention may use some space inside the electronic device 2, but an electronic device 2 incorporating said connection system 10 can have a reduced size. And, it is also less costly.
A first probe 31 comprises a second element 121 and is ready to be connected to the first element 111. A second probe 32 comprising a second element 122 is already connected to the first element 114. The first elements 112 and 113 are not presently used. The user mechanically plugs or unplugs each of the probes 31, 32 to the electronic device 2 by their locking mechanisms 15.
As illustrated in
The electronic device 2 comprises first elements organized according to a matrix arrangement, having rows and columns. The electronic device 2 also comprises a number of signal buses corresponding to the number of rows to interconnect the first elements belonging to said row.
Thanks to the above feature, a plurality of probes may be connected simultaneously, one on each row. The number of transducer elements can therefore be increased. By using two probes having for example 128 transducers elements, the imaging system can behave such as having a unique 256 transducer elements. Different probes can be also connected simultaneously: probes having different transducer elements arrangements (linear, curved, matrix), or probes for different use (a probe for imaging the medium, or a probe for medium treatment). Each signal bus may comprise electronic interface adapted to the use of the probes that can be connected to it (imaging or treatment). The electronic interface for example comprises amplifies, multiplexers, analog to digital converters, digital to analog converters, etc. . . . as it is well known.
For example, the electronic device of
According to a first variant, all the first elements 11 of the matrix arrangement may be independent from the other. Each first element 11 is for example embedded inside a connection unit comprising said first element 11, a single activation device 14, and a single third element 13 actuated by said activation device 14.
According to a second variant, the first elements 11 of a column (of index i) may be grouped into a connection unit that comprises the first elements 11ai, 11bi, a single activation device 14, and a single third element 13 actuated by said activation device 14. However one or two distinct probes can be connected to the single third element 13 of said connection unit. The probes are therefore independently mechanically plugged or unplugged to the connection unit (electronic device 2), but the single actuation device 14 electrically connect or the probes by moving said single third element 13 between the inactivated position and the activated position.
Such electronic device 2 can provide numerous configurations. For example, a first probe can be plugged to the first row of a column, and a second probe can be plugged to the second row of another column. In that case, both probes are independently controlled.
The probe 3 comprises a locking mechanism 15 in the form of a manual handle that is rotatable according to the insertion direction ID, said insertion direction being parallel to the activation direction AD. The locking mechanism comprises a locking shaft 16 adapted to be locked to the third element 13, via the connecting shaft 19.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/000421 | 2/19/2013 | WO | 00 |