JP2020071116A - thermometer - Google Patents

Abstract

To provide a thermometer in which, when a holder is used as a holding jig, a thermometer body is less likely to fall off the holder.SOLUTION: A thermometer 1 comprises a thermometer body 2 having an open hole 22 for holding use and a holder 3 having a cylindrical part 30 for accommodating the thermometer body. The cylindrical part 30 of the holder 3 has a retaining part 30a constituted of the tip portion of the cylindrical part 30 and press-fitted into the open hole 22, and a neck part provided at the rear end of the retaining part 30a. The open hole 22 and the cylindrical part 30 are constituted so as to assume a first engagement state in which the retaining part 30a is press-fitted into the open hole 22 and the inner edge of the open hole 22 engages with the neck part and a second engagement state in which the holder 3 is rotated around the center shaft of the cylindrical part 30 in the first engagement state and the degree of engagement is increased to be larger than in the first engagement state. In the second engagement state, as the degree of engagement of the retaining part 30a with the open hole 22 increases, it is possible to make the thermometer body 2 less likely to fall off the holder 3.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a thermometer used in cooking and the like.

  Conventionally, as a thermometer for cooking and beverages, a rod-shaped temperature sensor having a temperature sensor at a tapered tip and a temperature processing display unit for processing a signal from the temperature sensor and displaying the temperature are provided. A digital thermometer having a shape called a stick type or a pen type is known. Such a thermometer has a protective cover that covers the tip of the thermometer in addition to the thermometer body in order to prevent damage to the tapered tip or to prevent the tip from damaging the human body. Is equipped with. As this type of thermometer, for example, one having a safety cap into which a tapered tip is inserted is known (see, for example, Patent Document 1).

  Further, it is known that a protective cover for covering the tip end when the thermometer is not used is a holder for accommodating the whole of the rod-shaped temperature sensitive body, and the holder is used as a holder when the thermometer is used. For example, when using a thermometer, a digital thermometer is known that allows a user to securely measure the temperature by holding a holder connected to the thermometer main body at a position retracted from hot steam. Will be described with reference to FIGS. 14 and 15.

  This conventional thermometer 90 includes a thermometer main body 91 and a holder 92, as shown in FIGS. The thermometer main body 91 has a rod-shaped temperature sensitive portion 91a and a flat plate-shaped processing display portion 91b for performing temperature processing and display. The temperature sensing portion 91a has a temperature sensor at its tip portion 91c. The processing display unit 91b has a temperature display unit 91d that displays a temperature value obtained by processing the signal from the temperature sensor, and a through hole 91e into which the holder 92 is inserted. The holder 92 has a small diameter portion 92a which is inserted into the through hole 91e and a large diameter portion 92b which prevents the holder 92 from coming off when inserted into the through hole 91e.

  As shown in FIGS. 15A and 15B, the small diameter portion 92a of the holder 92 is inserted into the through hole 91e from the back side of the temperature display portion 91d, the large diameter portion 92b reaches the through hole 91e, and the thermometer The body 91 and the holder 92 are coupled to each other. The large-diameter portion 92b and the through-hole 91e are provided with an engaging portion in which the concave portion and the convex portion are fitted and fixed to each other by rotating in opposite directions after being inserted to a predetermined position. The user can measure the temperature with the thermometer 90 by gripping the end of the small diameter portion 92a of the holder 92, as shown in FIG. Therefore, at the time of temperature measurement, the user's hand can be positioned away from directly above the tip portion 91c having the temperature sensor, so that heat such as steam can be avoided, and the temperature display portion 91d is in front. The temperature displayed can be easily read because it can be located at.

JP, 2017-40527, A

  However, in the conventional thermometer as shown in FIG. 14 and FIG. 15 described above, when the large-diameter portion 92b and the through hole 91e are disengaged, the thermometer main body 91 falls off from the holder 92. There is.

  The present invention solves the above problems and provides a thermometer capable of preventing the thermometer main body from coming off the holder when the holder is used as a holder for the thermometer main body during temperature measurement. The purpose is to

  In order to achieve the above object, a thermometer of the present invention includes a thermometer main body having a through hole for holding, and a holder having a tubular part that accommodates a part of the thermometer main body. Has a retaining portion formed of the tip portion of the tubular portion and press-fitted into the through hole, and a constricted portion provided at the rear end of the retaining portion and having an outer circumference shorter than the outer periphery of the retaining portion. The through hole of the meter body and the cylindrical portion of the holder are engaged with each other by engaging the retaining portion of the cylindrical portion by press fitting into the through hole and fitting the inner edge portion of the through hole into the constricted portion. The second engagement member in the combined state, in which the holder is rotated about the central axis of the tubular portion in the first engagement state, and the degree of engagement between the retaining portion and the through hole is greater than that in the first engagement state. It is characterized in that it is configured so as to be brought into a combined state.

  According to the thermometer of the present invention, when the holder is used as a holder for the thermometer body during temperature measurement, the through-hole of the thermometer body and the tubular portion of the holder have the retaining portion of the tubular portion press-fitted. After being inserted into the through hole and the inner edge portion of the through hole is fitted and engaged with the constricted portion of the tubular portion to be in the first engaged state, the holder is rotated around the central axis of the tubular portion. As a result, the second engagement state is achieved. In the second engaged state, the degree of engagement between the retaining portion of the tubular portion and the through hole is greater than in the first engaged state, so that the thermometer body can be prevented from falling off the holder easily. .. Further, in the above-mentioned second engaged state, the retaining portion formed of the tip end portion of the tubular portion is engaged with the through hole, so that the thermometer main body and the holder can be coupled by a simple operation without changing the holder. The convenience can be improved.

(A) is a plan view of a thermometer according to an embodiment of the present invention, (b) is a rear view of the thermometer, and (c) is a side view of the thermometer. (A) is a top view of the thermometer main body of the same thermometer, (b) is a rear view of the same thermometer main body. (A) is a plan view of the holder of the same thermometer, (b) is a sectional view taken along the line AA of (a). Sectional drawing explaining the 1st engagement state which engaged the holder with the thermometer main body of the same thermometer, and the structure for electrical processing. The block diagram explaining the control system of the thermometer. The perspective view which shows the use condition of the same thermometer. (A) is a perspective view illustrating a procedure for engaging a holder with a thermometer body of the thermometer, and (b) is a perspective view showing a first engagement state in which the thermometer body and the holder are engaged with each other, FIG. 6C is a perspective view showing a second engagement state in which the thermometer main body and the holder are engaged with each other. (A) is sectional drawing explaining the dimension of the holding | maintenance penetration hole periphery of the same thermometer main body, (b) is a side view explaining the dimension of the retainer part periphery of the same holder, (c) is the same thermometer main body Sectional drawing which shows the 1st engagement state which the said holder engaged, (d) is sectional drawing which shows the 2nd engagement state which the said thermometer main body and the same holder engaged. (A) is a cross-sectional view including the central axis of the holder around the retaining portion of the same holder, (b), (c), and (d) are cross-sectional views taken along the line C-C and the line D-D of (a), respectively. , EE line sectional view. 9A is a cross-sectional view of the holder taken along a plane rotated by 90 ° about the cross-section of FIG. 9A, and FIGS. 9B and 9C are cross-sectional views taken along line FF of FIG. 9A. -G line sectional view, HH line sectional view. (A) (b) (c) is sectional drawing of the constricted part of the holder in the through-hole for holding | maintenance in the state which made the holder engage with the thermometer main body of the same thermometer, (a) is the 1st, respectively. FIG. 5 is a sectional view of an engaged state, (b) a transition state from a first engaged state to a second engaged state, and (c) a second engaged state. (A) and (b) are perspective views showing how the same thermometer is attached to and detached from a magnetic material wall, and (c) is a perspective view showing how the thermometer main body is taken in and out of a holder fixed to the magnetic material wall. (A) is a perspective view showing a first engagement state of a modification of the thermometer, (b) is a sectional view showing a first engagement state of the modification, and (c) is a second engagement view of the modification. Sectional drawing which shows a combined state. (A) is a plan view of a conventional thermometer, and (b) is a plan view of the thermometer main body of the same thermometer taken out from a holder. (A), (b) is a perspective view explaining the procedure which connects the conventional thermometer main body of FIG. 14 and a holder, (c) is a perspective view which shows the use condition of the conventional thermometer.

  Hereinafter, a thermometer according to an embodiment of the present invention will be described with reference to the drawings. As shown in FIGS. 1, 2, and 3, a thermometer 1 according to the present invention is a digital thermometer including a thermometer main body 2 and a holder 3 that houses the thermometer main body 2, and the holder 3 includes: It can be used as a holder for holding the thermometer main body 2 by the user during temperature measurement.

  The thermometer main body 2 is coupled to the rod-shaped temperature sensitive body 20 having the temperature sensor 10 at the tip portion 20a and the rear end side of the temperature sensitive body 20 and displays the temperature based on the signal from the temperature sensor 10. The unit 21 and a through hole 22 for holding provided in the temperature processing display unit 21 are provided. The temperature sensitive body 20 is a metal pipe with a closed tip, and is made of, for example, a stainless alloy.

  The temperature processing display unit 21 has a rectangular flat plate shape with rounded corners, the temperature sensitive body 20 is coupled to the end face on the front end side, and an oval through hole 22 is arranged near the rear end. The through hole 22 is formed so as to open in a direction orthogonal to the longitudinal direction of the temperature sensitive body 20, and the longitudinal direction of the opening faces the direction orthogonal to the longitudinal direction of the temperature sensitive body 20. The temperature processing display unit 21 has a temperature display unit 21a, a power switch 21b for turning on and off a power source, and a hold switch 21c for fixing and displaying an instantaneous temperature value at the time of measurement on the front surface thereof. Is equipped with.

  The temperature display unit 21a is a rectangular display unit that is long in the direction orthogonal to the temperature sensitive body 20, and is configured using, for example, a liquid crystal display device. The switches 21b and 21c are arranged along the temperature display portion 21a. The temperature processing display unit 21 is assembled by mounting the temperature sensitive body 20 or the electronic device in a resin-molded case, or by incorporating it. ABS resin or the like is used as the resin for the case. The configuration for electrical processing will be described later (see FIGS. 4 and 5).

  The holder 3 includes a tubular portion 30 having a hollow portion 30x for housing the temperature sensitive body 20, a flat plate portion 31 connected to the rear end side of the tubular portion 30 and wider than the tubular portion 30. The flat plate portion 31 is provided with a flat plate-shaped magnet 32 fixed to a surface not facing the central axis of the tubular portion 30. The flat plate portion 31 protects or supports the temperature processing display portion 21 from behind. Further, the flat plate portion 31 is also used as a grip portion for the user to hold in the hand when measuring the temperature. The magnet 32 is used to fix the holder 3 to a magnetic wall surface or the like by magnetic force (see FIG. 12 described later).

  The tubular portion 30 of the holder 3 has, in order from the front end side to the rear end side, a retaining portion 30a that is inserted into the through hole 22 and a constricted portion 30b having a cross section smaller than that of the retaining portion 30a. It is provided near the tip of the tubular portion 30. The retaining portion 30a is formed by the tip portion of the tubular portion 30. The constricted portion 30b is provided at the rear end of the retaining portion 30a and has an outer periphery shorter than the outer periphery of the retaining portion 30a. The retaining portion 30a and the constricted portion 30b are both structural bodies formed around the central axis of the tubular portion 30, and have a hollow portion 30x inside.

  Further, the tubular portion 30 has a slit 30d at the front and rear of the constricted portion 30b along the central axis of the tubular portion 30 in order to facilitate elastic deformation of the constricted portion 30b. Further, the tubular portion 30 has a mark 30c for rotational alignment on the rear end side of the constricted portion 30b of the tubular portion 30 and at an outer peripheral position rotated by 90 ° from the position of the slit 30d. .. The mark 30c may be one, or may be diagonally located with respect to the central axis of the tubular portion 30. Corresponding to this mark 30c, the temperature processing display portion 21 of the thermometer main body 2 has a mark 22b along the center line of the rear end face which is close to the through hole 22 (see FIG. 6).

  The mark 30c may be configured by a structure such as a concave portion or a convex portion, or may be visually configured by a color or a pattern. The tubular portion 30 and the flat plate portion 31 of the holder 3 are integrally formed of resin, for example. For example, ABS resin is used as the resin.

  Next, a configuration for electrically processing the thermometer 1 will be described with reference to FIGS. 4 and 5. The thermometer 1 includes a control unit 11 configured by mounting electronic components on a circuit board, a battery 12 serving as a drive source, and wiring for electrically connecting the electric components. The wiring is, for example, a covered wire that connects the temperature sensor 10, the battery 12, the temperature display unit 21a, the power switch 21b, the hold switch 21c, and the like to the control unit 11, a flexible circuit board, an elastic metal plate for a battery, and the like. The thermometer 1 has a waterproof structure so that electric components and electronic components are not deteriorated by moisture and the like, and the case of the temperature processing display unit 21 is sealed. The temperature processing display unit 21 has a battery lid 12a having a sealing structure, which is opened and closed when the battery 12 is replaced, on the surface (back surface) opposite to the side where the temperature display unit 21a is located. ..

  The control unit 11 determines a process of converting a signal from the temperature sensor into a temperature value, a process of driving the temperature display unit 21a to display the temperature value, and a temperature display when the hold switch 21c is pressed during temperature measurement. Processing such as the display state held over time is performed. The hold switch 21c is also used as a switch for canceling the hold display state. For the temperature sensor 10, for example, a thermistor element is used. As the battery 12, for example, a standard commercially available button battery is used, and the battery 12 can be easily replaced by removing the battery lid 12a. It should be noted that FIG. 4 shows a state in which the thermometer main body 2 and the tubular portion 30 of the holder 3 are coupled (first engagement state). This first engagement state will be described later.

  Next, the usage state of the thermometer 1 will be described with reference to FIG. The holder 3 is used as a holder for holding the thermometer body 2 by inserting the retaining portion 30a at the tip of the tubular portion 30 into the through hole 22 of the temperature processing display portion 21. The thermometer main body 2 and the holder 3 are coupled to each other with their longitudinal axes orthogonal to each other. In this state, for example, the user holds the temperature sensitive body 20 in the vertical direction by holding the flat plate portion 31 in his hand, and when viewing the temperature display portion 21b from the front to the front, the user can see the temperature display portion 21b in the horizontal direction in the horizontal direction. The temperature displayed digitally can be read.

  Next, with reference to FIG. 7, a procedure for connecting the thermometer main body 2 and the holder 3 and holding the thermometer main body 2 by the holder 3 and a structure of each part will be described. As shown in FIGS. 7A and 7B, in the retaining portion 30a, a cross section (see FIG. 9B) of the retaining portion 30a in a plane orthogonal to the central axis of the tubular portion 30 has the same cross section. It has an unequal shape that is long in one direction and short in the other direction in two orthogonal directions. The arrow a3 indicates the longitudinal direction (also referred to as the major axis direction) in the cross section. Further, the through hole 22 is formed in an oval shape at the rear end side (upper end side in the figure) of the temperature processing display portion 21. The opening of the through hole 22 has an oval shape that is long in the left and right, and an arrow a2 indicates the longitudinal direction (also referred to as the major axis direction).

  The through hole 22 has a ridge 22a provided on the inner surface thereof in the circumferential direction. The protrusion 22a forms an inner edge portion of the through hole 22, that is, a portion protruding inward. In the present embodiment, the ridge 22a is provided in a closed curved shape that is continuous with the entire inner periphery of the through hole 22. The opening formed by the inner edge of the protrusion 22 a is the narrowest opening portion of the through hole 22. The protrusion 22a is provided in a closed curve shape, but is not limited to such a shape in order to connect the thermometer main body 2 and the holder 3 to each other, and at least the upper and lower long sides of the elliptical shape of the through hole 22. It may be only a ridge in the direction (left and right direction in the figure).

  The upper and lower protrusions 22a extending in the left-right direction in the drawing inside the through hole 22 must be deformed by the member forming the retaining portion 30a inserted through the through hole 22 or the member forming the through hole 22. The upper and lower widths of the space are restricted so that they cannot pass through. The retaining portion 30a is press-fitted into such a space having a limited width. In the left-right direction of the through-hole 22 (direction of arrow a2), the opening width in the left-right direction of the through-hole 22 is wider than the width of the retaining portion 30a in the direction indicated by the arrow a3. There is no regulation.

  The retaining portion 30a has flattened thinning portions 30e on the upper and lower outer surfaces where the slits 30d are opened vertically. Due to the presence of these thinned portions 30e, the retaining portion 30a has a cross section of the retaining portion 30a formed by a plane orthogonal to the axial direction of the tubular portion 30 in one of two orthogonal directions (arrow a3). Direction) is long and the other direction is short. That is, the retaining portion 30a is formed thinner than the portion of the tubular portion 30 having the circular outer shape.

  The structure of the retaining portion 30a will be further described. The thinning portion 30e of the retaining portion 30a has a shape in which the side surface of the cylinder recedes in a planar manner toward the central axis side over a predetermined length from the tip of the tubular portion 30. The direction orthogonal to the plane surface of the meat removing portion 30e is the lateral direction in the above-described cross section of the retaining portion 30a. Similarly, the direction parallel to the plane surface of the meat removing portion 30e and orthogonal to the central axis of the tubular portion 30 is the longitudinal direction (arrow a3) in the cross section of the retaining portion 30a. In addition, in the present embodiment, the flesh removing portions 30e are provided on both sides of the central axis of the tubular portion 30 so as to face each other, but the embodiment is not limited to this aspect. It may be provided on only one side.

  The rear end surface of the retaining portion 30a has a planar shape orthogonal to the axial direction of the tubular portion 30. The side surface of the retaining portion 30a is composed of a cylindrical surface and a surface formed by the thinning portion 30e. The side surface of the retaining portion 30a and the rear end surface of the retaining portion 30a form an edge that is perpendicular to each other and cut up at a right angle. The outer edge portion of the rear end surface of the retaining portion 30a is a portion that comes into contact with the protrusion 22a of the through hole 22 and is caught and prevented from retaining.

  The through hole 22 and the retaining portion 30a are each formed by resin molding, and both of them are elastically deformable. For example, the thickness of the peripheral member forming the through hole 22 is small on the side where the mark 22b is present, which facilitates elastic deformation. In addition to the slit 30d provided to facilitate the elastic deformation of the tubular portion 30, the opening 30f provided at the tip of the tubular portion 30 facilitates the elastic deformation of the tubular portion 30. Has the effect of

  The constricted portion 30b is sandwiched between the rear end surface of the retaining portion 30a and the end surface of the cylindrical portion of the tubular portion 30, and is formed coaxially with the retaining portion 30a and the cylindrical portion of the tubular portion 30. It is a square columnar body. Thus, the constricted portion 30b has a cross section smaller than the cross section of the retaining portion 30a adjacent to both ends of the constricted portion 30b and the cylindrical portion of the tubular portion 30, and fits within the outer shape of the retaining portion 30a. Has an outer shape. The constricted portion 30b has a prismatic shape with the corner portions appropriately chamfered. Thus, the constricted portion 30b serves as a regulation member that regulates a change in the rotational state of the holder 3 around the central axis when the thermometer body 2 and the holder 3 are coupled.

  In the tubular portion 30, the retaining portion 30a is inserted into the through hole 22 in a state where the surfaces having the meat removing portions 30e are arranged vertically and the mark 30c is oriented in the lateral direction. That is, the insertion is performed with the through holes 22 and the retaining portion 30a in a state where the arrows a2 and a3 representing the longitudinal directions thereof are parallel to each other. This insertion is press-fitting performed with the through hole 22 and the retaining portion 30a elastically deforming. When the retaining portion 30a passes between the upper and lower protrusions 22a, insertion of the retaining portion 30a is completed.

  Upon completion of the insertion of the retaining portion 30a between the upper and lower protrusions 22a, the pressure (compressive stress) applied to the retaining portion 30a and the through hole 22 for press fitting is released. Then, the outer edge of the rear end surface of the retaining portion 30a comes to be positioned outside the inner edges of the upper and lower protrusions 22a, and the outer shape of the rear end surface of the retaining portion 30a is larger than the opening formed by the inner edge of the protrusion 22a. , The upper and lower parts are spread out. As a result, the rear end surface of the retaining portion 30a and the end surface of the ridge 22a contacting the rear end surface are engaged with each other, and the retaining portion 30a is restricted from coming out of the through hole 22, and the thermometer body 2 and the holder 3 are prevented. And are in a first engagement state in which they are coupled to each other.

  In this first engaged state, the inner edge portion of the through hole 22, that is, the protrusion 22a is fitted to the constricted portion 30b. In this first engaged state, the longitudinal direction of the oval shape of the through hole 22 (direction of arrow a2) and the direction along the surface of the retaining portion 30a formed by the beveled portion 30e (direction of arrow a3). , In the same direction as each other.

  In the first engagement state shown in FIG. 7B, as shown by the arrow R, when the holder 3 is rotated 90 ° around the central axis of the tubular portion 30, the thermometer main body 2 and the holder 3 are separated from each other. The second engagement state shown in FIG. 7C is obtained. In this state, the temperature is measured by the thermometer 1 using the holder 3 as a holder. In the second engagement state, the mark 22b on the temperature processing display portion 21 and the mark 30c on the tubular portion 30 are included in the same plane, and the user can easily confirm that the second engagement state. (See Figure 6). In this second engagement state, the longitudinal direction of the oval shape of the through hole 22 (arrow a2 direction) and the direction along the surface of the retaining portion 30a formed by the chamfered portion 30e (arrow a3 direction) are mutually opposite. The directions are orthogonal.

  The direction of the arrow a3 in the retaining portion 30a is the longitudinal direction of the cross section of the retaining portion 30a on the plane orthogonal to the central axis of the tubular portion 30. Therefore, in the second engagement state, the vertical width of the outer shape of the rear end surface of the retaining portion 30a is further greater than the vertical width of the opening formed by the inner edge of the protrusion 22a from the first engagement state. It will be in a spread state. For this reason, the area of overlap between the rear end surface of the retaining portion 30a and the side surface of the protrusion 22a in contact with the retaining portion 30a is larger than in the first engagement state. That is, the second engagement state is a state in which the degree of engagement between the retaining portion 30a and the protrusion 22a of the through hole 22 is greater than that in the first engagement state.

  Next, the retaining effect and the 90 ° rotation operation of the tubular portion 30 will be described with reference to FIGS. 8 to 11. As shown in FIG. 8A, the through hole 22 has an opening dimension D1 on the back side of the temperature processing display unit 21 and the temperature processing display unit 21 in the up-down direction that is a direction that restricts the rotation of the tubular portion 30. The opening dimension D3 on the front surface side and the dimension D2 between the inner edges of the upper and lower protrusions 22a are characteristic dimensions.

  Further, as shown in FIGS. 8B and 8D, the tubular portion 30 has, as its characteristic dimensions, a diameter d0 of a cylindrical outer shape portion of the tubular portion 30 and a thinning portion of the retaining portion 30a. The dimension d1 between the surfaces formed by 30e, the dimension d2 between the opposing surfaces in the direction along the surface formed by the leaning portion 30e in the constricted portion 30b, and the dimension d3 in the major axis direction of the retaining portion 30a (dimension d1 External dimensions of the retaining portion 30a in the direction orthogonal to the direction (1).

  Further, as a structural dimension for restricting the movement of the tubular portion 30 in the front-rear direction with respect to the temperature processing display portion 21 in a state where the holder 3 is coupled to the thermometer main body 2, the front-rear thickness W of the ridge 22a, There is a length (width) w of the constricted portion 30b. As the length w of the constricted portion 30b is larger than the thickness W of the rib 22a and the difference therebetween is smaller, the play in the front-rear direction of the tubular portion 30 at the time of engagement becomes smaller.

  In the present embodiment, the retaining portion 30a has a structure in which the chamfered portion 30e is formed in a cylindrical portion having the same diameter d0 as the cylindrical portion of the tubular portion 30. Therefore, the dimension d3 of the retaining portion 30a in the major axis direction is the same as the diameter d0 of the cylindrical portion of the tubular portion 30 (d3 = d0). Further, in the present embodiment, the opening dimension D1 of the through hole 22 on the back side of the temperature processing display section 21 and the opening dimension D3 of the through hole 22 on the front side of the temperature processing display section 21 are the same (D1. = D3). However, for example, the dimension d3 may be larger than the dimension d0, and in order to increase the dimension d3, the opening dimension D1 of the through hole 22 on the back side of the temperature processing display unit 21 may be increased in correspondence with the dimension d3. ..

  In the temperature processing display portion 21, the dimension D2 between the inner edges of the protrusions 22a is smaller than the opening dimensions D1 and D3 of the through hole 22 (D1, D3> D2). Further, in the tubular portion 30, the dimension d1 between the surfaces formed by the chamfered portion 30e in the retaining portion 30a is smaller than the diameter d0 of the cylindrical outer shape portion of the tubular portion 30, and further, the dimension d1 is smaller than the dimension d1. The dimension d2 between the opposed surfaces of the constricted portion 30b is small (d0, d3> d1> d2). In addition, since the retaining portion 30a is inserted into the protrusion 22a in the through hole 22 by press fitting between the respective component parts, the thickness of the retaining portion 30a is smaller than the dimension D2 between the inner edges of the protrusion 22a. The dimension d1 between the surfaces formed by the taking portion 30e is large (D2 <d1).

  Further, other magnitude relations of such dimensions can be appropriately set based on the design policy. For example, when the fitting condition of the protrusion 22a with respect to the constricted portion 30b is to be strengthened, the dimension d2 between the facing surfaces of the constricted portion 30b is made larger (D2 <d2) than the dimension D2 between the inner edges of the protrusion 22a. Then, the protrusion 22a may tighten the constricted portion 30b (the constricted portion 30b may be stretched). The fitting strength between the narrowed portion 30b and the protruding portion 22a can be adjusted by adjusting the thickness W of the protruding portion 22a in the front-rear direction and the length w of the narrowed portion 30b.

  As shown in FIG. 8C, in the first engagement state, which is a state immediately after the retaining portion 30a is inserted, the load for compressing the retaining portion 30a disappears, and the through-hole deformed at the time of insertion. The shapes of 22 and the retaining portion 30a return to the original dimensions. In this state, because the dimension d1 between the surfaces of the retaining portions 30a formed by the chamfered portions 30a is larger than the dimension D2 between the inner edges of the protrusions 22a (D2 <d1), the retaining portions 30a are protruded. The engagement state is maintained by retaining the stopper 22a. In this first engaged state, the dimension D2 between the inner edges of the protrusion 22a and the dimension d2 between the opposing surfaces of the constricted portion 30b, the opening dimension D3 of the through hole 22 on the front surface side of the temperature processing display portion 21 and the tubular shape. By setting the diameter d0 of the cylindrical outer shape portion of the portion 30 to be substantially equal to each other (D2≈d2 and D3≈d0), the combined state of the temperature processing display portion 21 and the tubular portion 30 can be It is possible to achieve a stable state with little wobble.

  In both the first engagement state and the second engagement state, the retaining portion 30a and the cylindrical portion of the tubular portion 30 are tubular in the through hole 22 without any elastic deformation. It is possible to freely rotate the portion 30 around the central axis. On the other hand, in the constricted portion 30b, since the diameter of the quadrangle in the diagonal direction is larger than the distance between the two opposing surfaces, the cylindrical portion 30 is not deformed unless either or both of the constricted portion 30b and the protrusion 22a are elastically deformed. Can not rotate around the central axis of. Therefore, the temperature processing display portion 21 and the tubular portion 30 in the first engagement state enter the second engagement state shown in FIG. 8D through such elastically deforming state.

  As described above, the constricted portion 30b is in the first engagement state and the second engagement state unless a force for causing elastic deformation is applied in the state where the thermometer body 2 and the holder 3 are coupled. Function as a restricting member that prevents the mutual changes in state. Further, when the user applies a force to change the first engagement state to the second engagement state, for example, the user can feel the feeling that the ridge 22a gets over the diagonal corner of the constricted portion 30b. Thus, it is possible to obtain a feeling that the temperature processing display portion 21 and the tubular portion 30 have reached the second engagement state.

  9 (a) to 9 (d) show the relationship between the tubular portion 30 and the protrusion 22a in the first engagement state, and FIGS. 10 (a) to 10 (d) show the second engagement state. 3 shows the relationship between the tubular portion 30 and the protrusion 22a. In the first engagement state, as shown in FIG. 9B, the major axis direction a3 in the cross section of the retaining portion 30a and the major axis direction a2 in the cross section of the protrusion 22a provided in the through hole are the same. In the direction. In the figure, the dimension d3 in the major axis direction and the dimension d1 in the minor axis direction of the retaining portion 30a are shown, and the dimension D2 in the minor axis direction of the opening of the protrusion 22a is shown.

  Here, half the difference between the dimension d1 of the retaining portion 30a in the minor axis direction and the dimension D2 of the opening of the protrusion 22a in the minor axis direction is defined as the height h1 (h1 = (d1-D2) / 2). The height h1 represents the degree of catching of the retaining portion 30a with respect to the protrusion 22a, and thus serves as an index indicating the degree of engagement between the retaining portion 30a and the through hole 22. The higher the index, the greater the degree of engagement.

  FIG. 9C shows a dimension d2 between the surfaces of the constricted portion 30b along the surface formed by the flesh-reducing portion 30e and a dimension d4 between the surfaces orthogonal to the direction of the dimension d2. In the present embodiment, these dimensions d2 and d4 are set so that the cross section of the constricted portion 30b is exactly included in the opening formed by the protrusion 22a.

  As shown in FIG. 9D, in the cross section of the cylindrical portion of the tubular portion 30, there is a portion protruding vertically from the area of the opening formed by the protrusion 22a, and this portion abuts the protrusion 22a. The insertion of the tubular portion 30 into the through hole 22 is stopped.

  In the second engagement state, as shown in FIG. 10B, the major axis direction a3 in the cross section of the retaining portion 30a and the major axis direction a2 in the cross section of the protrusion 22a provided in the through hole are orthogonal to each other. There is a direction to do. In this second engaged state, the index indicating the degree of engagement between the retaining portion 30a and the through hole 22 is the dimension d3 of the retaining portion 30a in the major axis direction and the dimension D2 of the opening of the protrusion 22a in the minor axis direction. The height h2 (h2 = (d3-D2) / 2), which is half the difference between

  Since the dimension d3 in the major axis direction of the retaining portion 30a is larger than the dimension d1 in the minor axis direction (d3> d1), the heights h1 and h2, which are indexes indicating the degree of engagement, are in the first engagement state. The height h2 in the second engagement state is larger than the height h1 in (2) (h1 <h2). Therefore, the degree of engagement between the retaining portion 30a and the through hole 22 is greater in the second engagement state than in the first engagement state.

  As shown in FIG. 10C, the cross section of the constricted portion 30b is also in the second engaged state in which the constricted portion 30b is rotated 90 ° with respect to the protrusion 22a from the first engaged state shown in FIG. 9C. Is exactly included in the opening formed by the protrusion 22a. This is because, in the present embodiment, the cross section of the retaining portion 30b is set in a square shape, and the dimensions d2 and d4 between the facing surfaces of the retaining portion 30b are the same (d2 = d4). by. These dimensions d2 and d4 are not limited to being the same as each other. For example, the dimension d4 may be larger than the dimension d2 (d2 <d4), and in this case, the constricted portion 30b is the protrusion. Inside of 22a, it is in a state of being stretched up and down with respect to the protrusion 22a.

  As shown in FIG. 10D, the relationship between the cylindrical portion of the tubular portion 30 and the opening formed by the protrusion 22a in the second engagement state is the case of the first engagement state (FIG. 9D). Is the same as.

  11 (a), (b), and (c) show the relationship between the shape of the protrusion 22a and the shape of the constricted portion 30b in the first engagement state, the transition state, and the second engagement state, respectively. In the first engagement state and the second engagement state, the constricted portion 30b is in a state of being stably sandwiched by the protrusion 22a. In the transition state, due to the presence of the slit 30d provided in the axial direction around the constricted portion 30b and the presence of the hollow portion 30x in the tubular portion 30 for housing the temperature sensitive body 20, the constricted portion 30b is formed. The constricted portion 30b is appropriately deformed so that the distance between the corners on the diagonal line of the cross section is shortened, and the inner diameter of the protrusion 22a in the vertical direction is appropriately enlarged.

  In the transition state, the retaining portions 30a at the front and rear positions of the constricted portion 30b and the cylindrical portion of the tubular portion 30 are elastically deformed, and the gap of the slit 30d in the constricted portion 30b is narrowed. Thereby, the respective portions of the constricted portion 30b that face each other across the slit 30d are translated so as to approach the central axis of the tubular portion 30, and the transition from the first engagement state to the second engagement state is easy. become. In the description of the configuration of each part of the thermometer 1, the terms such as up and down, left and right, and front and back with respect to the thermometer body 2 are used for convenience, but the thermometer 1 may be used in any space posture. it can.

  According to the thermometer 1 of the present embodiment, when the holder 3 is used as a holder for the thermometer body 2 during temperature measurement, the through hole 22 of the thermometer body 2 and the tubular portion 30 of the holder 3 are The retaining portion 30a of the tubular portion 30 is inserted into the through hole 22 by press fitting, and the inner edge portion of the through hole 22 is fitted and engaged with the constricted portion 30a of the tubular portion 30 to be in the first engagement state. After that, the holder 3 is rotated around the central axis of the tubular portion 30 to be in the second engagement state. In this second engaged state, the degree of engagement between the retaining portion 30a of the tubular portion 30 and the through hole 22 becomes greater than in the first engaged state, so that the thermometer main body 2 falls off the holder 3. Can be hardened. Further, in the second engagement state, the retaining portion 30a composed of the tip end portion of the tubular portion 30 and the through hole 22 are engaged, so that the thermometer main body 2 and the holder can be easily operated without changing the holder 3. 3 can be combined with each other, improving convenience.

  Further, in the conventional thermometer, when the small diameter portion 92a of the holder 92 shown in FIG. 15B is inserted into the through hole 91e, the axial position of the thermometer main body 91 with respect to the holder 92 and the rotational position around the axis are different. Indefinite. These positions are locked only when the thermometer main body 91 is moved to the position of the large diameter portion 92b and the large diameter portion 92b is engaged with the through hole 91e. As described above, the conventional thermometer is a one-step lock that is complicated to operate, whereas the thermometer according to the present embodiment is easy to operate and has a two-step lock, and the thermometer main body 2 is easily held by the holder 3. It can be used for convenience.

  Next, the storage of the thermometer 1 when not in use will be described with reference to FIG. The thermometer 1 is stored with the thermometer main body 2 housed in the holder 3. As shown in FIGS. 12 (a) and 12 (b), the holder 3 uses a fixing magnet 32 provided on a surface of the flat plate portion 31 that does not face the central axis of the tubular portion 30, and is used for a refrigerator. It can be stored by adsorbing and fixing it on a magnetic surface such as the door surface. In such a storage state, the thermometer 1 can be used also as a thermometer for measuring and displaying the room temperature because the temperature display portion 21a faces the front. Further, when the temperature is measured by holding the thermometer body 2 by hand without using the holder 3 as a holder, as shown in FIG. 12C, only the thermometer body 2 is taken out from the holder 3. Can be used.

  Next, a modified example of the thermometer 1 of the present embodiment will be described with reference to FIGS. 13 (a), 13 (b) and 13 (c). In the thermometer 1 of this modification, as shown in FIG. 13B, the thickness W ′ around the through hole 22 in the temperature processing display portion 21 is thin, and the thickness of the protrusion 22a in the front-rear direction in the above-described embodiment is small. It is set to the same as W (W '= W). In both the first engagement state and the second engagement state, the inner edge of the through hole 22 fits into the constricted portion 30b, and the retaining portion 30a and the through hole 22 engage with each other.

  Although it has been described that the opening shape of the through hole 22 is an elliptical shape in the above-described embodiment and its modification, the elliptical shape has an elliptical shape, an oblong shape, and rounded corners. It is a broad concept including a shape and a simple rectangular shape. Further, the cross-sectional shape of the protrusion 22a is not limited to the semicircular shape shown in FIG. 8 and may have a quadrangular cross section.

  It should be noted that the present invention is not limited to the above configuration, and various modifications can be made. For example, the chamfered portion 30e is not limited to a flatly formed shape, and may have an outer edge shape similar to the inner edge of the through hole 22 into which the retaining portion 30a is inserted, that is, the inner edge of the protrusion 22a. .. The retaining portion 30a is not limited to a case where the side surface of the cylinder has a flattened shape retreating portion 30e toward the central axis side over a predetermined length from the tip of the tubular portion 30, and the side surface of the cylinder is You may have the lean part 30e of the shape which receded to the central axis side in the convex curved surface shape. If the meat removing portion 30e is flat, manufacturing is easy. When the outer edge of the beveled portion 30e has a shape similar to the inner edge of the protrusion 22a, the height h1 (see FIG. 9B) representing the degree of engagement in the first engagement state can be increased. ..

  Further, in order to insert the retaining portion 30a into the through hole 22 and bring it into the first engagement state, it is not necessary that both the through hole 22 and the retaining portion 30a be elastically deformable, and either one is elastically deformable. It only needs to be deformable. Similarly, in order to change from the first engagement state to the second engagement state, at least one of the through hole 22 and the constricted portion 30b may be elastically deformable. The slits 30d for facilitating elastic deformation of the constricted portion 30b are not limited to being provided on both sides of the central axis of the tubular portion 30, and may be provided on only one side.

  In the above-described embodiment, the opening shape of the through hole 22 has a configuration in which the length along the longitudinal direction of the thermometer main body 2 is short, but the opening shape of the through hole 22 is not limited to such a configuration. If the length along the longitudinal direction of the thermometer main body 2 is different from the length along the direction orthogonal to the longitudinal direction, and the shorter length of the opening is a length capable of press-fitting the retaining portion 30a. Good.

  Further, when the deformability of the through hole 22 is used, among the members forming the through hole 22, the beam-like portion provided with the mark 22b is provided with one or several cuts or a continuous small cross-section portion, The through-hole 22 may be appropriately deformed when the retaining portion 30a is inserted and the constricted portion 30b is rotated. Further, the through hole 22 is not limited to the through hole having the closed outer periphery, and may be a through hole having a cut portion and having a C-shaped cross section.

1 Thermometer 10 Temperature Sensor 2 Thermometer Main Body 20 Temperature Sensitive Body 20a Tip (Temperature Sensitive Body Tip)
21 Temperature Processing Display Part 21a Temperature Display Part 22 Through Hole for Holding 22a Protrusions on Inner Surface of Through Hole 22b Mark 3 Holder 30 Cylindrical Part 30a Detachment Part 30b Constricted Part 30c Mark 30d Slit 30e Chamfer part 31 Flat Plate Part 32 Magnet

Claims (7)

A thermometer body having a through hole for holding,
A holder having a tubular portion that houses a part of the thermometer body,
The tubular portion is a constriction having a tip portion of the tubular portion that is press-fitted into the through hole, and an outer periphery that is provided at a rear end of the retaining portion and that has an outer circumference shorter than an outer periphery of the retaining portion. And a section,
The through hole of the thermometer main body and the cylindrical portion of the holder are
The retaining portion of the tubular portion is inserted into the through hole by press-fitting, and the inner edge portion of the through hole is fitted into the constricted portion to be engaged with the first portion,
In the first engagement state, the holder is rotated about the central axis of the tubular portion, and the degree of engagement between the retaining portion and the through hole is made larger than that in the first engagement state. 2 is configured to be in an engaged state,
A thermometer characterized by that. The through-hole has an oval-shaped opening,
The retaining portion has an unequal shape in which a cross section orthogonal to the central axis of the tubular portion is long in one of two orthogonal directions and short in the other,
In the first engagement state, the longitudinal direction of the oval shape of the through hole and the longitudinal direction of the unequal shape of the retaining portion are the same direction,
In the second engagement state, the longitudinal direction of the oval shape of the through hole and the longitudinal direction of the unequal shape of the retaining portion are directions orthogonal to each other.
The thermometer according to claim 1, wherein the thermometer is a thermometer. The through hole, the opening shape is an elliptical shape,
The retaining portion has a chamfered portion having a shape in which the side surface of the cylinder recedes toward the central axis side in a convex curved surface shape or a planar shape over a predetermined length from the tip of the cylindrical portion,
The constricted portion is a rectangular columnar body that is coaxial with the tubular portion, and has an outer shape that fits within the outer shape of the retaining portion,
The pair of opposed side surfaces of the square columnar body are surfaces in a direction along a surface formed by the meat removal portion of the retaining portion,
In the first engagement state, the longitudinal direction of the elliptical shape of the through hole and the surface of the retaining portion in the direction along the surface formed by the beveled portion are in the same direction,
In the second engagement state, a longitudinal direction of the elliptical shape of the through hole and a surface of the retaining portion along a surface formed by the chamfered portion are directions orthogonal to each other.
The thermometer according to claim 1, wherein the thermometer is a thermometer. The constricted portion has a quadrangular cross section orthogonal to the central axis of the tubular portion, and the first engagement state and the second engagement state with respect to the rotation of the holder around the central axis of the tubular portion. Functions as a regulating member that regulates the change of state between
The thermometer according to any one of claims 1 to 3, wherein the thermometer is a thermometer. The inner edge portion of the through hole is a protrusion provided in the inner circumferential direction of the through hole, and the protrusion engages with the constricted portion in the first and second engagement states.
The thermometer according to claim 1, wherein the thermometer is a thermometer. The tubular portion has a slit in the direction along the central axis of the tubular portion and the front and rear of the constricted portion,
The thermometer according to claim 1, wherein the thermometer is a thermometer. The holder has, on the rear end side thereof, a flat plate portion wider than the tubular portion, and a fixing magnet is provided on a surface of the flat plate portion that does not face the central axis of the tubular portion.
7. The thermometer according to claim 1, wherein the thermometer is a thermometer.

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