Flow Sensor, Tube to Die Interface, Tube to Chip Interface, Isolated Liquid Flow Sensor
Thermal sensing of liquid through the wall of standard tubing is generally impeded by the amount of surface contact between the tube and the sensing die. If thermal properties of liquid could be accurately sensed through the tubing, then the flow of liquid as it is passing through standard tubing could also be sensed. Physical contact between tubes and sensors is not typically much more than the point or line of contact where the outer radius of the tubing diameter contacts the flat surface of a die adapted with thermal a sensor.
Thermal flow sensors rely on the change in tubing wall temperature to sense the amount of flow through the tubing. To enhance sensitivity of a thermal flow sensor, it would be beneficial if more area of the standard tubing were in thermal contact with the sensing die.
In accordance with a unique feature, the present invention increases the area of contact on the tubing wall and establishes separate thermally conductive paths between the increased contact area and the sensing areas of the die.
In accordance with another feature, the invention provides more contact area and a precise clamping force between the flow sensor and the tube, tubing can be removed and replaced after initial manufacture of the device.
In accordance with another feature, a thermal sensor is provided that includes a die having a surface formed to accept the outer surface of tubing; a molded plastic part located on the die surface, said molded plastic part including flexible portions having a surface adapted to engage the bottom half of the circumference of standard tubing when the tubing is fully placed in the molded plastic part; conductive material selectively patterned on the surface of the flexible portions that engages the die surface; and retaining hardware adapted to secure the tubing against the molded plastic part and flexible portions when the retaining hardware is secured to the molded plastic part.
In accordance with other features, a thermal sensing device is described that includes a C-clamp-like thermal sensor formed from a die material and provided in the form of a C-clamp, said C-clamp-like thermal sensor adapted to receive tubing when an opening formed when the c-clamp-like thermal sensor is opened and substantially surrounding the tubing when the C-clamp-like thermal sensor is closed over the tubing. A ribbon cable coupled to the die material opposite the opening formed when the C-clamp-like thermal sensor is opened. Metal connections integrated on the inner surface of the C-clamp-like thermal sensor to enhance thermal conduction of the C-clamp-like sensor when it is in contact with tubing.
Referring to
The present inventors believed the flow of liquid as it is passing through standard tubing could also be sensed if thermal properties of liquid could be accurately sensed through the tubing. By improving the amount of physical contact between tubes and sensors, the present inventors improved the overall effectiveness of thermal sensors when used with standard tubing. As described in the background, thermal flow sensors rely on the change in tubing wall temperature to sense the amount of flow through the tubing. To enhance sensitivity of a thermal flow sensor, the present inventors provide contact of thermal sensor with more area of the standard tubing.
Referring to the top views of a sensor 200 according to features of the present invention shown in
Referring to the side view of
When the tubing 120 is in place, it forces the film comprising the molded plastic part 210 to conform to the circumference of the tubing and compresses it between the die surface 227 and the tubing wall 127. Location features on the molded plastic part 210 and the film 210 allow for precise positioning of the conductive pattern with respect to the die sensor 200 areas.
Referring to the side view of
In another embodiment shown in the perspective view shown in
Referring to the perspective view of
Conduction is heat transferred by means of molecular agitation within a material without any motion of the material as a whole. For heat transfer between two plane surfaces, such as in thermal liquid flow sensor applications, the rate of conduction heat transfer is Q/t=kA(T2−T1)/d, where:
Q=heat transferred in time=t
k=thermal conductivity of the barrier
A=area
T=temperature
d=thickness of barrier
Using metal or other thermally conductive material to make contact in between the tube 120/520 and sensor 200/700 can help reduce the thermal contact resistance because the material's contact properties will increase the contact area A due to deformation of metals and higher thermal conductivity of metals (Ag and Cu have 400 times higher thermal conductivities than that of glass).
Where metals are used, the thermal conductivity can be quite high, and those metals which are the best electrical conductors are also generally the best thermal conductors. At a given temperature, the thermal and electrical conductivities of metals are proportional. So thermal resistance can be introduced similarly to electrical resistance. Three (3) thermal resistors can be found in series where metal rings are used on tubing: the resistor of the liquid tube, Rt; the resistor due to contact, Rc; the resistor of the sensor die, Rd.
A sensor's sensitivity can be shown as a function of R, S=f (R,x,y,z . . . ), R=Rt+Rc+Rd. The variation of sensor sensitivity due to movement of the tubing causes the change of Rc (δRc), or the contact resistance change. The use of epoxy between tubing and a die keeps the Rc constant, so the result is stable performance. Without epoxy, δRc and Rc are too big, and they contribute a lot of change to R and sensitivity.
For a disposable design, obviously, the biggest challenge is to keep Rc constant. Metal contact can be used to reduce Rc and δRc, the result being a smaller δRc and Rc over R.
The use of metal rings would reduce the Rc because Rc=f(A, F . . . ), (A is contact area, F is force) metal is easier for deformation, Indium, soft gold (or Silver, etc) metal rings on both sides would increase contact area A, so it would reduce the Rc significantly.
Conforming coatings offer significant enhancement to the thermal contact conductance, with Indium exhibiting the most significant enhancement. In principle, the same result should be realizable with any conforming coating. Previous work with gold coating has shown that although the conductance was improved as the result of gold coating the surfaces, the improvement was nowhere near the magnitude of that realized with Indium. There are two reasons for this. Firstly, gold is still much harder than Indium. Secondly, the thickness of Indium was a lot higher than that of the gold. Where mass production and cost are factors, it is believed that thermally conductive ceramics will be used in greater numbers for sensor made as described herein.
Number | Name | Date | Kind |
---|---|---|---|
4333354 | Feller | Jun 1982 | A |
4358947 | Greene et al. | Nov 1982 | A |
4399696 | Feller | Aug 1983 | A |
4559483 | Jundt et al. | Dec 1985 | A |
4612806 | Feller | Sep 1986 | A |
4649756 | Feller | Mar 1987 | A |
4890499 | Feller | Jan 1990 | A |
20020073772 | Bonne et al. | Jun 2002 | A1 |
Number | Date | Country | |
---|---|---|---|
20070017286 A1 | Jan 2007 | US |