JP7237320B1 - sensor - Google Patents

Abstract

An object of the present invention is to provide a sensor having a structure that contributes to improvement in measurement accuracy. The sensor includes a case 10 of a sensor 1 inserted into the body of a cow and an electrode pair 500 arranged on the outer circumference of the case 10, and data measured using the electrode pair 500 is collected. , the sensor 1 capable of transmitting data through the wireless communication line Rw using the data transmission means 3 built in the case, and the electrodes 51, 51 constituting the electrode pair 500 are connected to the entire electrode 51, respectively. It is surrounded by the outer surface of the case 1 made of insulating material. [Selection drawing] Fig. 1

Description

TECHNICAL FIELD The present invention relates to a physical condition measuring device used for physical condition management of quadrupedal mammals such as livestock, and more particularly to a sensor for measurement of a physical condition measuring device used for predicting ovulation and parturition of cattle.

Sensors used for ovulation prediction and delivery prediction of cows include, for example, a sonde 1 (see Patent Document 1) having an electrode 3 on the front end side and an electrode 4 on the rear end side with an insulating range 5 interposed therebetween, There is a delivery prediction notification system that attempts to perform delivery prediction accurately (see Patent Document 2).

JP-A-58-169444 JP 2006-125231 A

By the way, in the recent development of measuring instruments, many of them improve the measurement accuracy by improving the data processing technology. There is only a sonde 1 having a structure in which electrodes 3 and 4 are arranged with the .
Even if the measurement accuracy can be improved by improving the data processing technology, there is a limit in some cases.

The present invention has been made in view of such problems, and an object of the present invention is to provide a sensor having a structure that contributes to improvement in measurement accuracy.

The invention according to the present application comprises a sensor case that is used by being inserted into the body of a cow, and an electrode pair arranged on the outer periphery of the case, and data measured using the electrode pair is A sensor capable of transmitting data through a wireless communication line using data transmission means built in the case, wherein each electrode constituting the electrode pair is covered with an insulating material of the case over the entire circumference of the electrode. Surrounded by a structured exterior.

The two electrodes forming the electrode pair are arranged in a state of being aligned in the longitudinal direction of the sensor via an inter-electrode outer peripheral surface formed between the two electrodes.

A plurality of electrode pairs are arranged on the outer periphery of the case, and an inter-electrode pair outer peripheral surface is arranged between the plurality of inter-electrode outer peripheral surfaces, and each electrode pair outer peripheral surface is , adjacent to the outer peripheral surface between the electrodes.

In addition, the case includes a front outer peripheral surface formed at an end on one longitudinal end side that is inserted before the electrodes when inserted into the body, and the outer peripheral surface between the electrode pairs is formed by: It is adjacent to the outer peripheral surface of the tip portion.

Further, the electrode has a convex electrode surface protruding to the outside of the case.
Each electrode is arranged in a recess formed on the outer periphery of the case.
Furthermore, it is more preferable that each electrode is arranged in an individual recess.

It also has a corner formed along the outer periphery of the electrode.
Further, a groove is formed adjacent to the outer peripheral surface of the electrode.

More preferably, at least part of the electrode surface of the electrode installed in the recess is adjacent to the outer peripheral surface between the electrode pairs.

Further, the support member is arranged at a position closer to the other end side, which is the opposite side, than the one end side of the case. and a non-contact area on the other side in the longitudinal direction of the contact area and the contact area with the internal body formed at the end on the one end side and its periphery. When the boundary is located on the outer peripheral surface between the electrical pairs and the movement of the case with respect to the internal surface occurs with the movement of the cow, the boundary is formed It moves in the longitudinal direction along the outer peripheral surface between the electrode pairs.

By using the sensor of the present invention, it is possible to further improve the accuracy of measurement inside livestock such as cattle, and to further improve the accuracy of physical condition management of livestock, especially ovulation prediction and delivery prediction.

FIG. 3 is a conceptual diagram showing a usage state of the sensor according to the present invention; 1 is a perspective view showing Example 1 of a sensor according to the present invention; FIG. 3 is an enlarged plan view showing the tip of the sensor shown in FIG. 2; FIG. FIG. 3 is an exploded plan view showing the structure of the sensor (excluding the support member) shown in FIG. 2; FIG. 4 is an exploded front sectional view showing a CC section of the tip portion of the sensor shown in FIG. 3; FIG. 4 is a front sectional view showing a CC section of the tip portion of the sensor shown in FIG. 3; FIG. 4 is a side sectional view showing a BB section of the tip portion of the sensor shown in FIG. 3; It is an explanatory view for explaining the use state of the sensor according to the present invention. 5 is an exploded front cross-sectional view (corresponding to FIG. 5 of Example 1) showing Example 2 of the sensor according to the present invention. FIG. FIG. 10 is a front cross-sectional view of the tip portion of the sensor shown in FIG. 9 (a view corresponding to FIG. 6 of Example 1);

1... sensor (Example 1), 1A... sensor (Example 2), 1x... longitudinal direction of the sensor,
2...control module (sensor control means), 3...wireless communication module (data transmission means),
4...Temperature measurement module, 5...Battery module,
10...Case unit (case, insertion case),
20... rear case, 20s... outer peripheral surface of rear case, 20x... axis of rotational symmetry (central axis) of cylindrical part,
21... cylindrical part, 21a... opening on one end side, 22... case rear end (sensor rear end),
23 ... fitting protrusion (other connection part),
30... Tip case, 30x... Rotational symmetry axis (central axis) of tip case (cylinder part),
31... cylindrical portion, 31a... opening on the other end side, 31s... outer peripheral surface, 31w... outer peripheral body (peripheral member),
32 ... Case tip (sensor tip, one end),
32s...the outer peripheral surface of the tip of the case (the outer peripheral surface of the tip), 33...the fitting recess (one connecting part),
40...Terminal mounting part (mounting hole), 40m...Mounting hole for negative terminal (-terminal mounting hole),
40p... Mounting hole for positive terminal (+ terminal mounting hole), 40x... Rotational symmetry axis (central axis),
41...large diameter portion, 41b...bottom surface, 41w...hole inner peripheral side surface,
42...small diameter portion, 42a...outer opening rim, 42w...inner peripheral side of hole,
50…Terminal, 50x…Axis of rotational symmetry (central axis),
51... electrode part (electrode), 51p... + electrode (+ electrode part), 51m... - electrode (- electrode part),
51a... electrode surface, 51b... back surface, 51e... outer peripheral edge, 51t... top, 52... shaft part, 52a... hollow part,
500 ... electrode pair (both electrode parts 51, 51),
60... Corner (groove), 70... Supporting unit (supporting member), 71... Mounting part, 72... Leg,
80... Terminal (Example 2), 81... Electrode portion (electrode), 81a... Electrode surface, 81e... Peripheral edge,
800 ... electrode pair (both electrode parts 81, 81),
C1: the intersection of the axis of rotational symmetry 40x and the first circumference line;
C2...Intersection point of the axis of rotational symmetry 40x and the second circumference line, Cf...Cow, Cs...Body surface,
Da: contact area on the distal side (contact area with the inner body surface),
Db: non-contact area on the posterior end side (non-contact area with the internal surface), Dv: boundary (boundary area),
E ... Hollow space,
H1: height dimension of the electrode portion 51, H2: height dimension of the shortest portion of the large diameter portion 41,
H3: the height dimension of the longest portion of the large-diameter portion 41,
L1: distance between electrode pairs, L2: distance between pair electrodes, Lc: outer tangent line,
P... outline, Rw... wireless communication line, R... bodily fluid (vaginal bodily fluid, liquid having conductivity),
S1... first orthogonal plane, S2... second orthogonal plane,
Sb: Peripheral surface between electrode pairs, Si: Peripheral surface between electrodes, Sw: Electrode pair area, Vh: Lateral direction (viewing direction),
α: Minor angle (acute angle in this embodiment).

Next, an embodiment of the sensor according to the present invention will be described.
The sensor 1, as shown in FIGS. 1 and 2, is used by being inserted into the body of the cow Cf (inside the vagina here), and detects an electric It can be used as a measuring terminal (measuring child device) of a measuring device capable of measuring resistance (or electrical conductivity) (see FIGS. 1 and 2). Moreover, the sensor 1 incorporating the temperature measurement module can be used as a measurement terminal capable of measuring body temperature (vaginal temperature) as well.
As a measurement device (not shown) using the sensor 1, for example, a prediction device (prediction system) that predicts ovulation, delivery, and the like can be given.

As shown in FIG. 2 , the sensor 1 of Example 1 includes a case unit (sometimes referred to as an insertion case or simply a case) 10 that forms the outer shape of the sensor 1 .
In the case unit 10, there are various components such as a control module 2 used for controlling the measurement operation of electrical resistance and body temperature, a wireless communication module 3, a temperature measurement module 4 including a temperature probe, and a battery module 5 as a power source. of sensor components are incorporated. In other words, the sensor 1 uses a wireless communication line Rw (see FIG. 1) to transmit and receive various data such as measurement data to and from the transmitter/receiver (measuring device main body) outside the body of the cow Cf. It is a formula sensor.
It should be noted that a well-known method can be used for the configuration and installation method of installing components such as modules in the case 10, or the sealing structure and sealing method (molding method) after installation, so it is shown in the figure. Also, the description is omitted, and the wiring and the like between each module are also omitted from the illustration.
Also, for data measurement control, wireless communication control, and battery operation control, well-known control techniques can be used, so detailed description thereof will be omitted. In other words, for example, an operation of measuring an electrical resistance value using an electrode (electrode portion) 51 of a terminal 50 described later, an operation of measuring temperature using a temperature measurement module, an operation of transmitting and receiving various data including measurement data, etc. Detailed descriptions of various operations that can be executed in the processing operations of are omitted.

The case unit 10 includes a hollow rear case 20 and a hollow front case 30 detachably attached to the rear case 20. As shown in FIG. The case unit 10 (that is, the sensor 1) configured by connecting the front case 30 and the rear case 20 is a member whose longitudinal direction is the direction of the central axes 20x and 30x of the front case 30 and the rear case 20. .
Further, both the rear case 20 and the front case 30 are made of insulating resin (insulating material). A terminal 50 used for measuring the electrical resistance value is attached to the front case 30 . As will be described later, the terminal 50 is an energized portion during data measurement and is made of a conductive material.

As shown in FIG. 4, the rear case 20 has a hollow cylindrical portion 21, and one end of the cylindrical portion 21 is an opening 21a. A fitting protrusion (the other connecting part) 23 used for connection with a fitting concave part (the one connecting part) 33 described later of the front case 30 is formed in the opening on the one end side. On the other hand, on the other end side of the cylindrical portion 21, a case rear end portion (hereinafter sometimes referred to as a sensor rear end portion) 22 that is integrally connected to the cylindrical portion 21 is formed. The case rear end portion 22 is a projecting portion that protrudes toward the other end side of the central axis 20x extending in the longitudinal direction of the tubular portion 21, and the other end side of the rear case 20 is closed by the case rear end portion 22. there is
Further, the front case 30 is a member having a hollow cylindrical portion 31, and the other end side of the cylindrical portion 31 of the front case 30 is an opening 31a. A fitting concave portion (one connecting portion) 33 used for connection with the fitting convex portion 23 of the rear case 20 is formed in the opening on the other end side. On the other hand, on one end side of the tubular portion 31, a case tip portion (hereinafter sometimes referred to as a sensor tip portion) 32 that is integrally connected to the tubular portion 31 is formed. The case front end portion 32 is a projecting portion that protrudes toward the other end side of the central axis 30x of the tubular portion 31, and the front end side of the front case portion 30 is closed by the case front end portion 32. As shown in FIG.

The fitting concave portion 33 of the front case 30 and the fitting convex portion 23 of the rear case 20 can be connected by fitting in a mutually detachable manner. The inner space (hollow space, see FIG. 5) E of the case unit 10 formed by the connection incorporates sensor components such as the various modules described above. In the case unit, the sensor components such as the modules described above are installed, the terminal 50 is installed in the case 30, and necessary wiring connection between the terminal 50 and the control module etc. is performed, and the sensor operation is performed. After ensuring the possible state, it is preferable to seal by a well-known molding process or the like.

As shown in FIG. 5, the cylindrical portion 31 of the front case 30 is composed of an outer peripheral body 31w, which can be called a shell body having a predetermined thickness and partitioning the inside and outside of the case unit 10. As shown in FIG. The outer peripheral body 31w (cylindrical portion 31) of the tip case 30 is formed with a terminal mounting portion (hereinafter simply referred to as a mounting hole) 40 used for mounting the terminal 50 for measurement.
In this embodiment, the attachment hole 40 is a through hole penetrating the front case 30, which is the outer peripheral body 31w.

More specifically, the mounting hole 40 has a large-diameter portion 41 adjacent to the outer peripheral surface 31s of the cylindrical portion 31 (the outer peripheral body 31w) and a small-diameter portion 42 adjacent to the hollow space E inside the outer peripheral body 31w. and Both the large-diameter portion 41 and the small-diameter portion 42 are portions formed by cylindrical hole inner peripheral side surfaces 41w and 42w surrounding the through hole.

The large-diameter portion 41 and the small-diameter portion 42 are arranged such that their axes of rotational symmetry (central axes) are located on the same central axis 40x. Therefore, the outer opening edge 42a of the small diameter portion 42 is formed at the position of the bottom surface 41b of the large diameter portion 41, although the mounting hole 40 before the terminal 50 is mounted can be seen from the outside of the case.
The circular outer peripheral edge of the bottom surface 41b of the large-diameter portion 41 and the circular outer opening edge 42a of the small-diameter portion 42 are arranged concentrically. It is an arrangement that surrounds the edge 42a over the entire circumference. Therefore, the bottom surface 41b of the large-diameter portion 41 has a so-called donut shape (hollow disk shape), and can be said to be a stepped surface caused by the difference in diameter between the large-diameter portion 41 and the small-diameter portion .

The terminal 50 for measurement is attached to the mounting hole 40, and includes an electrode portion (hereinafter sometimes simply referred to as an electrode) 51 attached to the large-diameter portion 41 of the mounting hole 40, and a small-diameter portion of the mounting hole 40. and a shaft portion 52 that is inserted into the portion 42 .
The shaft portion 52 is connected to the control module 2 via wiring (not shown) for conducting electricity, and is integrally formed on the back side of the electrode portion 51 . In addition, the shaft portion 52 has a hollow portion 52a that can be used for wiring connection or the like.

The shaft portion 52 is a cylindrical member, and its diameter is such that it can be inserted into the small diameter portion 42 of the mounting hole 40 without backlash, that is, the diameter matches the inner diameter of the small diameter portion 42 . Further, the back surface 51b of the electrode portion 51 is a flat surface that can be in close contact with the bottom surface 41b of the large diameter portion 41, as described later. Therefore, when the terminal 50 is attached to the attachment hole 40, the attachment hole 40 is blocked by the terminal 50. As shown in FIG. The contact between the bottom surface 41b of the large-diameter portion 41 and the back surface 51b of the electrode portion 51 positions the electrode portion 51 with respect to the mounting hole 40 in the direction of the axis of rotational symmetry 40x. The terminal 50 can be fixed to the case by using a well-known method such as screwing or adhesion, and illustration of a specific fixing structure is omitted.
Also, the attached terminal 50 is connected to the control module 2 by wiring (not shown). In addition, in this embodiment, illustration of wiring is omitted for the sake of convenience.

With the terminal 50 attached to the attachment hole 40, the electrode portion 51 has an electrode surface 51a (see FIG. 6) facing the outside of the case unit 10, a back surface 51b on which the shaft portion 52 is arranged, and an outer surface 51b. and a peripheral edge 51e.
The electrode surface 51a is a contact surface that comes into contact with an object to be measured, and is a convex surface (convex surface) with a bulging central portion. It should be noted that the object to be measured in this embodiment is typically the body fluid R.
The outer peripheral edge 51e is an outer peripheral edge surface arranged between the electrode surface 51a and the back surface 51b, is in contact with the outer peripheral edge of the electrode surface 51a and the outer peripheral edge of the back surface 51b, and is in contact with the outer peripheral edge of the electrode surface 51a and the back surface 51b. It can be said that In this embodiment, the electrode portion 51 (electrode surface 51a) is a projecting portion that is surrounded by an outer peripheral edge and has a bulging central portion.
The outer peripheral edge 51e of the electrode portion 51 has a larger diameter than the outer peripheral edge of the shaft portion 52, and both outer peripheral edges are arranged concentrically. In other words, the planar rear surface 51b of the electrode portion 51 has a so-called donut shape. When the terminal 50 is attached to the attachment hole 40 , the rear surface 51 b of the electrode portion 51 is brought into contact with the flat bottom surface 41 b of the large diameter portion 41 .

The outer peripheral edge 51e of the electrode portion 51 has the same diameter as the hole inner peripheral side surface 41w of the large diameter portion 41. As shown in FIG.
As shown in FIG. 6, when the terminal 50 is attached to the mounting hole 40 of the case unit 10, the outer peripheral edge 51e of the electrode portion 51 (that is, the electrode surface 51a) is in contact with the hole inner peripheral surface 41w of the large diameter portion 41. The small diameter portion opening 42a of the bottom surface 41b of the large diameter portion 41 is closed by the terminal 50. As shown in FIG. Therefore, the electrode portion 51 of the terminal 50 attached to the attachment hole 40 is installed in a bottomed concave portion formed on the outer periphery of the front case 30 when focusing on the sensor 1 as a finished product. It can be said that there is

Further, as shown in FIG. 3, the electrode portion 51 (the outer peripheral edge 51e thereof) of the terminal 50 attached to the attachment hole 40 is made of the insulating material of the tip case 30 (case unit 10) over the entire circumference. It is attached to the front case 30 while being surrounded by the configured outer surface.
The outer surface of the front case 30 (case unit 10) is exposed to the outside of the sensor 1 among the outer peripheral surface 31s of the front case 30 and the hole inner peripheral side surface 41w of the large diameter portion 41 of the mounting hole 40. It's about the face.
That is, in the sensor 1 of the present embodiment, the electrode portion 51 is surrounded by the outer peripheral body 31w forming the cylindrical portion 31 of the front case 30, and the outer peripheral surface of the front case 30 is a part of the outer surface. It can be said that it is surrounded by 31s.

Further, as shown in FIG. 7, the convex electrode portion 51 (that is, the electrode surface 51a) is installed in a convex state toward the case outer side of the central axis 40x of the mounting hole 40. As shown in FIG.

As shown in FIG. 6, the top (top ridgeline) 51t of the convex electrode portion 51 is exposed to the outside of the front case 30 (facing the outside of the attachment hole 40 in the central axis direction). ).
Therefore, as will be described later, when the sensor 1 is used, contact between the electrode surface 51a and the bodily fluid R is ensured, and fluidity is ensured.

As shown in FIGS. 2 to 7, a plurality of mounting holes 40 are formed in the front case 30. As shown in FIG. Specifically, the cylindrical portion 31 of the front case 30 has a positive terminal mounting hole 40p (hereinafter referred to as a + terminal mounting hole) and a negative terminal mounting hole 40m (hereinafter referred to as a - terminal mounting hole). A plurality of each are formed (see FIG. 5).
In this embodiment, the +terminal mounting hole 40p is arranged closer to the front end of the case than the -terminal mounting hole 40m. It should be noted that the − terminal mounting hole 40m may be arranged closer to the front end of the case than the + terminal mounting hole 40p.

Here, for convenience of explanation of the configuration, orthogonal planes S1 and S2 (see FIG. 6) orthogonal to the central axis 30x of the front case 30 are assumed.
At this time, each positive terminal mounting hole 40p (see FIG. 5) is arranged in such a manner that its rotational symmetry axis 40x extends along the same orthogonal plane (hereinafter referred to as first orthogonal plane) S1. (See Figure 6).
A plurality of (four in this embodiment) positive terminal mounting holes 40p are arranged along the circumferential direction on the outer peripheral surface 31s of the tip case 30 with an interval distance (inter-electrode pair distance) L1 therebetween. (See FIG. 7).
Further, in the sensor 1 of this embodiment, the four positive terminal mounting holes 40p having the same shape are arranged at regular intervals in the circumferential direction. In other words, the plurality of positive terminal mounting holes 40p are arranged so that the rotationally symmetrical axes 40x of the adjacent positive terminal mounting holes 40p, 40p are orthogonal to each other.
Similarly, each of the terminal mounting holes 40m is arranged in such a manner that its axis of rotational symmetry 40x extends along the same orthogonal plane (hereinafter referred to as second orthogonal plane) S2 (see FIG. 6). .
A plurality of (four in this embodiment) -terminal mounting holes 40m are arranged in the circumferential direction on the outer peripheral surface 31s of the front case 30 with a spacing distance L1 therebetween. can. In addition, the four -terminal mounting holes 40m of the same shape are arranged at regular intervals in the circumferential direction. In other words, the plurality of −terminal mounting holes 40m are arranged in a state in which the rotationally symmetrical axes 40x of the adjacent −terminal mounting holes 40m, 40m are orthogonal to each other.

The number of + terminal mounting holes 40p and - terminal mounting holes 40m is the same (four places), and four + terminal mounting holes 40p and - terminal mounting holes 40m are four sets of terminal mounting holes 40p and 40m. constitutes The positive terminal mounting holes 40p and the negative terminal mounting holes 40m of each set are arranged in the longitudinal direction X1 of the case and spaced apart from each other.

In other words, assuming a cylindrical surface that coincides with the outer peripheral surface 31s of the cylindrical portion 31 of the tip case 30, as shown in FIG. An intersection point C1 can be assumed, and similarly an intersection point C2 between this cylindrical surface and the center axis 40x of the terminal mounting hole 40m can be assumed.
The + terminal attachment hole 40p and the - terminal attachment hole 40m are arranged such that both intersections C1 and C2 are positioned on a straight line extending in the longitudinal direction X1 along the outer peripheral surface 31s.
The distance between the positive terminal mounting hole 40p and the negative terminal mounting hole 40m, which constitute each set, is the same. distance, see Fig. 3) is the same as L2.
In the following description, the electrode (electrode portion) 51 attached to the + terminal attachment hole 40p may be referred to as the + electrode 51p, and the electrode (electrode portion) attached to the - terminal attachment hole 40m may be referred to as the + electrode 51p. 51 may be referred to as - electrode 51m.

Next, as shown in FIG. 3, both electrode portions 51, 51 (hereinafter referred to as electrode pairs 500) of both terminals 50, 50 attached to the + terminal attachment hole 40p and the - terminal attachment hole 40m of each set. ), define two circular outlines P defined on the outer peripheral surface of the tip case 30 (same as the outer peripheral edge 51e of the electrode portion 51 in FIG. 3, which is a plan view). do.
In this embodiment, the outline P is also the opening edge of the large-diameter portion 41 (hole inner peripheral side surface 41w) of the terminal mounting portion 40. As shown in FIG.
In addition, outer tangent lines Lc and Lc, which are straight lines that circumscribe both of the two contour lines P and P, are defined.

Then, the area of the outer peripheral surface 31s (hereinafter referred to as the inter-electrode outer peripheral surface Si) surrounded by the inner contour line located on the side close to each other and both outer tangent lines Lc and Lc among the two contour lines P is , defines for a plurality of electrode pairs 500 .
Specifically, the inter-electrode outer peripheral surface Si is a cross-slanted area with cross-slanted lines in FIG. 3 for convenience.
In other words, the inter-electrode outer peripheral surface Si (see FIG. 3) is located between the two mounting holes 40p and 40m forming the set on the outer peripheral surface 31s of the tip case 30, that is, the two electrodes (electrodes part) This is the part that exists between 51 and 51.
Therefore, when the two electrodes 51, 51 constituting each electrode pair 500 are energized, the energized current mainly conducts the body fluid R adhering to or adjacent to the inter-electrode outer peripheral surface Si between the electrodes 51, 51. Therefore, it can be said that the measured electrical resistance value is mainly the value measured for the body fluid R adhering to or adjacent to the inter-electrode outer peripheral surface Si.

Also, an area (hereinafter referred to as electrode pair area Sw) surrounded by the outer contour line, which is the side apart from each other, and both outer tangent lines Lc and Lc of both contour lines P is determined for each electrode pair 500. .
Specifically, the electrode pair area Sw is the entire area of the hatched areas hatched for convenience in FIG. 3 and the cross hatched areas therebetween.
That is, the electrode pair area Sw is a case surface region surrounding the electrode surfaces 51a, 51a of the two electrode portions 51, 51 forming the electrode pair and the inter-electrode outer peripheral surface Si positioned therebetween.

The plurality of electrode pairs 500 are arranged at intervals (inter-electrode pair distance) L1 (see FIG. 7). Note that the interval L1 is an equal interval.
That is, each electrode pair 500 is arranged in such a manner that the outer peripheral surface 31s of the tip case 30 exists between another electrode pair 500 adjacent thereto.
Here, the outer peripheral surface 31s arranged between the adjacent electrode pairs 500, 500 is particularly referred to as an inter-electrode pair outer peripheral surface Sb (see FIG. 3).
That is, the inter-electrode pair outer peripheral surface Sb is a portion of the outer peripheral surface sandwiched between (the outer tangential lines Lc of) the adjacent electrode pair areas Sw.
It can be said that the inter-electrode outer peripheral surface Si and the inter-electrode pair outer peripheral surface Sb, which are adjacent to each other, are connected to each other.
Furthermore, the inter-electrode pair outer peripheral surface Sb is adjacent to the electrode pair area Sw, adjacent to each of the electrodes 51, 51 forming the electrode pair 500 in the electrode pair area Sw, and each of the electrodes forming the electrode pair 500. It is adjacent to and continues to the electrode surface 51a of the electrode 51, and is adjacent to and continues to the inter-electrode outer peripheral surface Si between the two electrodes 51,51.

Each electrode pair-to-electrode outer peripheral surface Sb is located on the tip side (one end side) of the electrode pair 500 (more specifically, the + electrode 51p on the tip side) on the tip side in the longitudinal direction X1. and continues to the outer peripheral surface 32 s of the case tip portion 32 . In addition, the outer peripheral surface Sb between each electrode pair is on the rear end side (other end side), and is closer to the rear end side in the longitudinal direction X1 than the position of the electrode pair 500 (more specifically, the position of the -electrode 51m on the rear end side). It continues to a certain outer peripheral surface 31s and continues to the outer peripheral surface 20s of the rear case 20. As shown in FIG.
Then, the inter-electrode outer peripheral surface Si is connected to the adjacent inter-electrode pair outer peripheral surfaces Sb, Sb on both sides in the circumferential direction of the outer peripheral surface, and the outer peripheral surface of the tip case 30 is connected to the inter-electrode pair outer peripheral surfaces Sb, Sb via the inter-electrode pair outer peripheral surfaces Sb. 31s, and further to the outer peripheral surface 32s of the case tip portion 32. As shown in FIG.

In the sensor 1 of this embodiment, the distance between the + terminal mounting hole 40p and the - terminal mounting hole 40m, that is, the distance L2 between the + electrode 51p and the - electrode 51m that constitute each electrode pair 500 (see FIG. 3) is shorter than the distance L1 (see FIG. 7) between adjacent +electrodes 51p, 51p (-electrodes 51m, 51m).
That is, the circumferential width dimension L1 of the inter-electrode pair outer peripheral surface Sb is longer (wider) than the length dimension of the shortest distance L2 in the longitudinal direction X1 of the inter-electrode outer peripheral surface Si.

As shown in FIG. 2, the sensor 1 includes a support unit (support member) 70 that can be detachably attached to the rear case 20. As shown in FIG.
The support unit 70 includes a mounting portion 71 used for attachment to the rear case 20 and leg portions 72 provided on the mounting portion 71 .
The mounting portion 71 is an annular member having a hollow portion that can be externally inserted into the rear case 20 . The support unit 70 can be detachably attached to the case unit 10 by externally inserting this hollow portion into the rear case 20 .
The support unit 70 is attached so as to be positioned near the rear end side (other end side) of the case unit 10 . As for the fixing structure, since a well-known structure can be adopted, description and illustration thereof are omitted.
The leg portion 72 is a rod-shaped member extending radially outward from the outer circumference of the mounting portion 71 . The mounting portion 71 is integrally formed with three legs 72 arranged at regular intervals.
The support unit 70 ensures a stable installation state of the sensor, and the number of legs is not limited to three as long as the stable installation state can be secured. For example, a configuration of 2 or more and 6 or less can be mentioned.

Next, the use condition of the sensor 1 of this embodiment will be described.

As schematically shown in FIG. 2, the sensor 1 to which the support unit 70 is attached is used by being inserted into the body of the cow Cf (inside the vagina here). The inside of the body is mainly the inside of tube-shaped internal organs such as the inside of the intestinal tract and the inside of the vagina.

The sensor 1 has four electrode pairs 500, one or more electrode pairs 500 are arranged vertically below the sensor 1, and one or more electrode pairs 500 are arranged vertically above the sensor 1. placed in

Then, the two electrodes 51, 51 constituting each electrode pair 500 of the sensor 1 are energized, and the electric resistance value (of the body fluid R) between the two electrodes 51, 51 for each electrode pair 500 is measured.
In this embodiment, the electrical resistance values are measured simultaneously for each of the four electrode pairs 500 . The measurement interval includes continuous measurement and intermittent measurement at predetermined time intervals. The measurement interval in this example was 10 minutes.
The electrical resistance value data obtained by the measurement is then transmitted to an extracorporeal measuring device (not shown) using the wireless communication line Rw by the transmitting/receiving module 3 together with other related data.
Data such as electrical resistance data are used to detect changes in the physical condition of the cow Cf, such as ovulation and delivery.
Various methods of using the measurement data are conceivable. In this example, the minimum value among the four electrical resistance values measured simultaneously was used to detect changes in the physical condition of the cow Cf, such as ovulation and delivery.

By the way, the amount of bodily fluid R secreted by a cow Cf, which is a living organism, fluctuates.
Therefore, as a result of intensive research from the viewpoint of ensuring the stability of measured values, in conventional sensors, the actual amount of body fluid between electrodes and the state of body fluid R are not necessarily stable, resulting in an insufficient amount of body fluid. I found that there is a possibility.
As a result of further research, it was found that it is preferable to prevent fluctuations in physical measurement conditions in the sensor 1 and its surroundings, such as the state of contact between the electrode 51 and the body fluid R, as much as possible. This is probably because if the physical measurement conditions are likely to fluctuate, it becomes difficult to determine whether or not changes in the measurement data such as the electrical resistance value are caused by changes in the physical condition of the cow Cf. Therefore, it is preferable that the structure of the sensor 1 is excellent in measurement stability.

In this regard, each electrode 51 of the sensor 1 of the present embodiment is an electrode, which can also be called a button type, surrounded by an outer surface made of an insulating material over the entire circumference. The two electrodes 51, 51 constituting the 500 are arranged in a state of being aligned in the longitudinal direction X1 via the inter-electrode outer peripheral surface Si between both electrodes, and the inter-electrode outer peripheral surface Si corresponding to the measurement area is Since the region has a predetermined width and is sandwiched between the outer peripheral surfaces Sb, Sb between the electrode pairs on both sides, the contact state between the electrode 51 and the body fluid R is excellent in stability, and the measurement stability is excellent.
Further, the electrode 51 has a convex electrode surface 51a protruding outside the case 10. In this respect as well, the contact state between the electrode 51 and the body fluid R is excellent, and the measurement stability is excellent.

In addition, in relation to fluctuations in the amount of body fluid R secreted, further research was conducted from the viewpoint of ensuring the accuracy of the measured value of electrical resistance. It has been found that there is a possibility that circulation and flow of the body fluid R may be insufficient. In order to sensitively detect a change in the physical condition of the cow Cf based on the electrical resistance value of the body fluid R, it can be said that it is preferable that the electrical resistance value of body fluid R that is as fresh as possible can be measured.

Regarding this point, the sensor 1 of the present embodiment has a plurality of electrode pairs 500 arranged on the outer periphery of the case, and an inter-electrode pair outer peripheral surface Sb made of an insulating material between a plurality of inter-electrode outer peripheral surfaces Si. Each inter-electrode outer peripheral surface Si continues to the adjacent inter-electrode pair outer peripheral surface Sb, and the inter-electrode pair outer peripheral surface Sb continues to the outer peripheral surface 32s of the case tip portion 32, or is installed in the recess. At least a part of the electrode surface 51a of the electrode 51 has a structure in which it is adjacent to and connected to the outer peripheral surface Sb between the electrode pairs, so the circulation and fluidity of the body fluid R are excellent, and the measurement accuracy is improved. excellent for letting

In addition, focusing on the fact that the sensor is installed inside the body of a living body such as a cow, and the contact state of the sensor with bodily fluids is not necessarily constant, we conducted a thorough study on the measurement stability. FIG. 8 is a schematic diagram showing an installation state of the sensor 1 for convenience.

The outer peripheral surface 32s (see FIG. 8) of the case tip portion 32 of the sensor 1 shown in FIG. It is in a state of being in contact with body fluid R directly.
On the outer surface of the sensor 1, the front end portion 32 of the case and its surroundings have a front end side contact area Da in contact with the internal surface Cs through the body fluid R. As shown in FIG.
On the other hand, the support unit 70 is installed on the rear end side of the outer periphery of the sensor 1, and a rear end non-contact area Db relatively not in contact with the internal surface Cs is generated.
As a result, a boundary Dv (hereinafter sometimes referred to as a boundary region) is generated between the front end side contact region Da and the rear end side non-contact region Db.
It can be said that the sensor installation state in which the boundary region Dv is formed on the outer circumference of the sensor 1 is a situation in which the retention, circulation, or movement of the bodily fluid R on the outer circumference of the sensor 1 is likely to be promoted. For example, the boundary region Dv can be called a region where so-called surface tension tends to act, or a region where the action of surface tension changes greatly.
Furthermore, the border region Dv having such characteristics has the characteristic of moving due to the movement of the cow Cf.
The sensor 1 of this embodiment in such an installed state has a structure excellent in circulation and fluidity of the body fluid R on the inter-electrode-pair outer peripheral surface Sb.

Next, a sensor 1A of another embodiment (embodiment 2) according to the present invention will be described.

The sensor 1A of this alternative embodiment differs in the configuration of the terminals 80 from the configuration of the terminals 50 of the sensor 1 described above (see FIG. 9).
Therefore, here, mainly the configuration of the terminal 80 that constitutes the electrode pair 800 of the sensor 1A and the configuration related thereto will be described.
In addition, in the description of the sensor 1A here, the same reference numerals are given to the components common to the sensor 1 described above, and the description thereof may be omitted.

As shown in FIG. 9, the terminal 80 of the sensor 1A of this embodiment is common to the terminal 50 in that the electrode surface thereof is a convex surface, but the electrode surface 81a of the terminal 80 is spherical. The configuration differs from the electrode surface 51a of the terminal 50 of the first embodiment in that respect. The electrode surface 81a of the terminal 80 is not limited to a spherical surface, and may be a curved surface such as a hyperboloid or an ellipsoid.

As shown in FIG. 9, the convex electrode portion 81 (that is, the electrode surface 81a) is installed in a convex state toward the case outer side of the central axis 40x of the mounting hole 40, (facing the outer world in the central axial direction of the mounting hole 40).
Both the electrode portion 81 and the shaft portion 52 can be said to have rotationally symmetrical shapes, and are arranged so that the rotationally symmetrical axes (central axes) of the electrode portion 81 and the shaft portion 52 are positioned on the same central axis 50x. there is

As shown in FIG. 10, a corner (groove) 60 is formed adjacent to (the outer peripheral edge 81e of) the electrode surface 81a and sandwiched between the electrode surface 81a and the hole inner peripheral side surface 41w.
The electrode surface 81a and the hole inner peripheral side surface 41w forming the corner 60 are in contact with each other forming a minor angle α (see FIG. 10, an acute angle in this embodiment) at the position of the outer peripheral edge of the electrode surface 81a. , and has a V-shaped cross section that widens toward the outside in the radial direction of the front case 30 . When the electrode surface 81a and the hole inner peripheral side surface 41w are in contact with each other forming an acute angle as in the present embodiment, the formed corner has a shape that can be called a groove 60 having a V-shaped cross section.

As shown in FIG. 10, when the top 51t of the terminal 80 is viewed from the horizontal direction Vh (see FIG. 7), the electrode portion 81 (that is, the electrode surface 81a) can be viewed, and the terminal 80 is mounted on the front case. Attached to 30. That is, it can be said that the electrode surface 81a is attached in a state of being exposed in the lateral direction (viewing direction).
The horizontal direction Vh, which is the visible direction, is a direction orthogonal to the central axis 40x of the mounting hole 40 in which the terminal 80 is mounted, and also orthogonal to the longitudinal direction 1x of the case.
Further, the height dimension H1 of the electrode portion 81 (from the bottom surface 51b to the top 51t) is the length dimension H2 of the shortest portion of the height dimension (from the bottom surface 41b to the upper end opening) of the large diameter portion 41 (see FIG. 7). ) can be said to be longer.
The height dimension H1 of the electrode portion 81 is equal to or less than the length of the longest portion of the height dimension H3 of the large diameter portion 41 (see FIG. 10). When the height dimension H1 of the electrode portion 81 and the height dimension H3 of the longest portion of the large-diameter portion 41 are the same as in this embodiment, the electrode surface 81a can be visually recognized from the horizontal direction Vh and is exposed in the horizontal direction. It can be said that the
In the sensor 1 having such a configuration, contact between the electrode surface 81a and the body fluid R is reliably ensured during use, and fluidity is also ensured.

Sensors according to the present invention are not limited to those described in the embodiments.
Sensors modified without departing from the spirit of the invention are included in the scope of the invention.

For example, the subject using the sensor 1 is not limited to the cow Cf, but can also be used in four-legged mammals such as livestock.

In addition, although the material of the case unit 10 is polypropylene resin in this embodiment, it is not limited to this. resin material can be used.
Although the material of the terminal 50 is stainless steel in this embodiment, it is not limited to this, and a conductive material such as aluminum or aluminum alloy, which is well known as a material for electrodes, can be used.

Also, although there are four pairs of electrodes 500 and 800 in this embodiment, any number of pairs may be provided.

Moreover, the sensor 1 may be configured without the support member 70 . Regardless of whether the sensor 1 is provided with the support member 70 or not, the body fluid around the sensor 1 is excellent in circulation as described above.
The sensor 1 having the support member 70 is placed in contact with the internal body surface Cs at the position of the sensor tip 32, and is excellent in circulating the body fluid R at the position of the sensor tip 32.

Claims (4)

It comprises a sensor case that is used by being inserted into the bovine body, and an electrode pair that is arranged on the outer circumference of the case,
A sensor capable of transmitting data measured using the electrode pair through a wireless communication line using data transmission means built in the case,
Each electrode constituting the electrode pair is surrounded by an outer surface of the case made of an insulating material over the entire circumference of the electrode,
The case has a tubular portion, and a case distal end portion formed at one end in the longitudinal direction of the case, which is inserted prior to the electrode pair when inserted into the body. and
A support member arranged at a position closer to the other end side, which is the opposite side, than the one end side of the case,
When the case is inserted into the body, the case is in contact with the internal surface of the insertion destination at the positions of the support member and the case distal end , and a contact area with the internal internal surface formed in the case distal end and its periphery. and a non-contact area on the other side in the longitudinal direction of the contact area is installed so that a boundary is formed,
The two electrodes that constitute the electrode pair are arranged on the outer peripheral surface of the cylindrical portion in a state of being aligned in the longitudinal direction,
The outer peripheral surface of the cylindrical portion is continuous with the outer peripheral surface of the tip portion, which is the outer peripheral surface of the convex tip portion of the case,
The two electrodes constituting the electrode pair are arranged via an inter-electrode outer peripheral surface formed between the two electrodes,
A plurality of the electrode pairs are arranged on the outer peripheral surface of the cylindrical portion ,
An inter-electrode pair outer peripheral surface is arranged between the adjacent electrode pairs,
Each outer peripheral surface between the electrode pairs is arranged in a state adjacent to the outer peripheral surface between the electrodes,
The inter-electrode pair outer peripheral surface arranged between the plurality of electrode pairs is arranged on the outer peripheral surface of the tubular portion, and the tip formed on the one end side opposite to the other end side. a sensor located adjacent to the outer peripheral surface of the body ; The inter-electrode outer peripheral surface is continuous with the adjacent inter-electrode outer peripheral surface,
The outer peripheral surface between the electrode pairs continues to the adjacent tapered outer peripheral surface of the tip,
The electrode pair arranged between the electrode pair outer peripheral surfaces is arranged at a position adjacent to the tip portion outer peripheral surface,
2. The sensor according to claim 1, wherein when the case is inserted into the body, the boundary is formed on the outer peripheral surface of the cylindrical portion on which the electrode pairs and the outer peripheral surface between the electrode pairs are arranged. 3. The sensor according to claim 2, wherein the longitudinal direction, which is the arrangement direction of the two electrodes forming the electrode pair, is a direction extending from the contact area side to the non-contact area side. 4. The sensor according to claim 2 or 3, wherein the distance between two electrodes forming said electrode pair is shorter than the distance between said plurality of electrode pairs.

Images