KR101945142B1 - Magnet attraction-type temperature sensor and method for manufacturing same - Google Patents

Abstract

A temperature sensor which is attracted to a measurement object by a magnetic force includes a dish type contact member 14, a thermocouple cable 13 to which a thermocouple portion is connected to the inner surface side of the dish type contact member 14, A lower main body case 11B for holding the platy contact member 14 so that the bottom face of the die contact member 14 is exposed, a magnet 12, and a lower main body case 11B And the upper body case 11A for holding the magnet 12 inside the lower case body 11B with the magnet adsorption type temperature sensor can reduce the number of parts and simplify the assembling work.

Description

TECHNICAL FIELD [0001] The present invention relates to a magnet adsorption type temperature sensor and a manufacturing method thereof. [0002] MAGNET TYPE TEMPERATURE SENSOR AND METHOD FOR MANUFACTURING SAME [0003]

TECHNICAL FIELD [0001] The present invention relates to a temperature sensor which is attracted to a measurement object by a magnetic force.

There are various temperature sensors that measure the temperature, and the measurement method varies depending on the type of sensor. However, when measuring the temperature of a certain object, basically, the temperature sensor is contacted with the object to be measured, good.

When the object to be measured is made of a ferromagnetic material when the temperature sensor is brought into contact with the object to be measured, the magnet is used, and the attachment or detachment of the object is very simple, Is used.

A technology relating to a temperature sensor using such a magnet is disclosed in Patent Document 1. [

[Patent Document 1] Japanese Patent Application Laid-Open No. 2005-315591

Figs. 11 to 13 show a conventional magnet adsorption type temperature sensor. Figs. 12A and 12B are diagrams showing a process of forming the contact plate 101 and the thermocouple 102, Figs. 13A to 13C are views showing a magnet adsorption type temperature sensor 100 in accordance with the present invention.

As shown in Fig. 13 (c), the conventional magnet adsorption type temperature sensor 100 has a contact plate 101 to which a thermocouple 102 is connected to the back surface of two heads And the magnet 103 is provided inside the contact plate 101 to attract the object to be measured of the ferromagnetic material by the magnetic force, that is, the contact plate 101 to which the thermocouple is connected to the back face the object to be measured.

In this magnet attracting temperature sensor 100, the thermocouple 102 is welded to the contact plate 101 of the plate spring as shown in Fig. 12 (a) (Fig. 12 (b)), which requires bending work.

As shown in Fig. 13 (b), the magnet 103 is disposed inside the member formed as shown in Fig. 12 (b) by bending, and the contact between the thermocouple 102 and the magnet 103 It is necessary to provide some distance x in Fig. 13 (b). The reason why the contact between the thermocouple 102 and the magnet 103 is avoided is that there is a fear that the accuracy of temperature measurement may be lowered when the thermocouple 102 is brought into contact with the magnet 103. As a result, since the distance between the object to be measured and the magnet 103 becomes long, the attracting force is weakened. In the conventional magnet attracting temperature sensor 100, the magnetic force is concentrated by providing the yoke member 105 in order to compensate for the lack of magnetic force. However, c), there is a problem that assembling work of each member becomes troublesome. 13 (a), it is necessary to mount the magnets 103 in the yoke member 105, and as shown in Fig. 13 (b), the contact plate 101 and the magnets 103 ) Into the yoke member 105 is required. Further, a complicated operation was required for the processing of the wire rod (wire rod) 108 connected to the thermocouple 102 and drawn out.

SUMMARY OF THE INVENTION In view of the above, it is an object of the present invention to provide a magnet adsorption-type temperature sensor and a method of manufacturing the same that can reduce the number of parts and simplify the assembling work in a temperature sensor that is attracted by a magnetic force to a measurement object The purpose.

(Configuration 1)

A magnet adsorption type temperature sensor which is attracted by a magnetic force to a measurement object, comprising: a dish type contact member contacting the measurement object; a thermocouple cable to which a thermocouple portion is connected to the inner surface side of the dish type contact member; And a body case for holding the magnet and holding the dish-shaped contact member so that the bottom of the dish-shaped contact member is exposed.

(Composition 2)

The magnet adsorption-type temperature sensor according to Claim 1, further comprising a gap-forming member for forming a predetermined gap between the dish-shaped contact member and the magnet.

(Composition 3)

A lower main body case for holding the dish-like contact member so that the bottom surface of the dish-shaped contact member is exposed; and a lower main body case fitted to the lower main body case, And the upper main body case is provided on the upper surface of the upper main body case.

(Composition 4)

The magnet adsorption-type temperature sensor according to Structure 3, wherein the upper main body case is provided with a gap-forming member and an engaging member for holding the magnet.

(Composition 5)

The thermocouple cable according to any one of the constitutions 1 to 4 described in any one of the constitutions 1 to 4, wherein an engaging portion is formed on the thermocouple cable, and an engaging portion engaging with the engaging portion is formed on either the main body case or the dish- temperature Senser.

(Composition 6)

Wherein the main body case is provided with an opening for pulling out the thermocouple cable and the main body case is provided with a cable holding portion (holding portion) for changing the drawing direction of the drawn thermocouple cable A magnet adsorption-type temperature sensor according to any one of Structures (1) to (5).

(Composition 7)

A method for manufacturing a magnet adsorption type temperature sensor which is attracted by a magnetic force to a measurement object, comprising the steps of: connecting a thermocouple portion of a thermocouple cable to an inner surface side of a dish contact member; A step of engaging an engaging portion of the thermocouple cable with an engaging portion of the lower main body case mounted on the lower main body case so as to be lengthened, a step of inserting (inserting) a magnet into the upper main body case, And a step of fitting the lower main body case to the upper main body case and the lower main body case.

According to the magnet adsorption type temperature sensor of the present invention and the manufacturing method thereof, the number of parts can be reduced and the assembling work can be simplified.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a magnet adsorption type temperature sensor according to the present invention, wherein (a) is a lower perspective view, (b) is an upper perspective view
2 is an exploded perspective view of a magnet adsorption type temperature sensor according to the present invention
(A): a perspective view, (b): a top view, and (c): a side view
4 is a perspective view showing an upper body case;
(B): a side view, (c): a bottom view, and (d) another side view. [Fig. 5]
6 is a perspective view showing a lower main body case;
(B): a side view, (c): a bottom view, and (d) another side view of the lower main body case.
8 is a view showing an assembly process of a magnet adsorption type temperature sensor according to the present invention
Fig. 9 is a view for explaining the drawing of the thermocouple cable, and Fig. 9 (a) is a view showing drawing in the lateral direction, and Fig. 9 (b)
10 is a view showing another example of the dish-shaped contact member;
11 is an exploded perspective view showing a conventional magnet adsorption type temperature sensor
12 is a view for explaining a manufacturing process of a conventional magnet adsorption type temperature sensor;
13 is a view for explaining a manufacturing process of a conventional magnet adsorption type temperature sensor;

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are one form of embodying the present invention, and the present invention is not limited thereto.

Fig. 1 is a view showing a magnet adsorption-type temperature sensor according to the present invention. Fig. 1 (a) is a lower perspective view, and Fig. 1 (b) is an upper perspective view. 2 is an exploded perspective view of a magnet adsorption type temperature sensor.

1 and 2, the magnet adsorption type temperature sensor 1 is a temperature sensor that is attracted to a measurement target by magnetic force. The magnet adsorption type temperature sensor 1 is a temperature sensor that attracts the object to be measured, A thermocouple cable 13 to which a thermocouple portion is connected, a magnet 12, and a main body case 11.

The main body case 11 has a lower main body case 11B for holding the bottom side of the dish-shaped contact member 14 so as to be exposed therefrom and a lower main body case 11B which is fitted on the lower main body case 11B, And a main body case 11A.

3 (a) is a perspective view, Fig. 3 (b) is a top view, and Fig. 3 (c) is a side view.

As shown in the figure, the dish type contact member 14 provided in the magnet adsorption type temperature sensor 1 of the present embodiment is formed in a dish shape as a basic mode. That is, it has a circular bottom surface portion 141, a side surface portion 142, and a flange portion 143. The dish-shaped contact member 14 is formed using a material having a high thermal conductivity (stainless steel in this embodiment). By forming the plate-like shape, it can be easily formed by press working. In other words, the dish-shaped contact member 14 in the present embodiment is formed in a shape that can be formed by one press working.

Figs. 4 to 5 are views showing an upper main body case 11A provided in the magnet adsorption-type temperature sensor 1 of the present embodiment. Fig. 4 is a perspective view, Fig. 5A is a top view, 5 (c) is a bottom view, and Fig. 5 (d) is another side view.

The upper main body case 11A includes an engaging member 11A1 for holding the magnet 12, an engaging member 11A2 for engaging the lower main case 11B, and a lead- A cable retaining portion 11A3 for changing the direction, and a side wall 11A4.

Three engagement members 11A1 are formed in the present embodiment so that the outer peripheral portion of the upper main body case 11A in the circular shape at the top surface (top view) is in an even positional relationship . The engaging member 11A1 has a claw protruding from its distal end to the inner circumference side and seals the magnet 12 by the claw. Further, as will be described later, the engaging member 11A1 also functions as an interval forming member for forming a predetermined gap between the dish-like contact member 14 and the magnet 12.

In the present embodiment, two engagement members 11A2 are formed so as to be spaced apart from each other by approximately 180 DEG from the outer peripheral portion of the upper main body case 11A having a circular shape in the upper surface. The engaging member 11A2 is formed with a claw protruding from its distal end toward the outer circumference and engages with the lower case 11B by the claw.

The side wall 11A4 is formed at a position opposed to a cutout portion 11B5 formed in the lower main body case 11B to be described later and has a width substantially equal to the width of the thermocouple cable 13, And is formed in a wide width.

The cable retaining portion 11A3 is formed on a side surface of a portion in which the side wall 11A4 is formed and has two ribs symmetrically arranged in a substantially L- .

6 to 7 are views showing the lower main body case 11B provided in the magnet adsorption type temperature sensor 1 of the present embodiment. Fig. 6 is a perspective view, Fig. 7 (a) 7 (c) is a bottom view, and Fig. 7 (d) is another side view.

The lower main body case 11B includes a hole 11B1 for exposing a bottom surface portion 141 of the dish type contact member 14 and a hole 11B1 for exposing the dish type contact member 14 in a dish- A bottom edge portion 11B2 for supporting the female portion 143 of the contact member 14, an engagement portion 11B3 for engaging with the blood (hole) 13B of the thermocouple cable 13, (Fitting hole) 11B4 that engages with the engaging member 11A2 of the engaging portion 11A and a cutout portion 11B5 formed by notching a part of the side portion.

Since the bottom portion 141 of the dish-shaped contact member 14 is circular in this embodiment, the hole 11B1 is formed in the bottom portion 141 of the dish-shaped contact member 14, The bottom surface portion 141 is formed as a circular blood hole having a diameter enough to be inserted therethrough. Also, the bottom edge portion 11B2 is formed accordingly. That is, the hole 11B1 is formed to be larger than the bottom surface portion 141 of the dish-like contact member 14 and smaller than the valley portion 143 of the dish-shaped contact member 14. [

The engaging portion 11B3 is formed at a position where the cutout portion 11B5 is formed, and in this embodiment, it is a cylindrical projection, and its height is formed to be at least higher than the thickness of the thermocouple cable 13. [

The claws 11B4 are configured to catch a claw formed at the distal end of the engaging member 11A2 of the upper body case 11A.

The cutout portion 11B5 is formed by notching a part of a side portion formed in the outer peripheral portion of the lower side main body case 11B in a circular shape on the upper face and is substantially the same as the width of the side wall 11A4 of the upper side body case 11A Or is slightly wider than the width.

Next, the assembling process of the magnet adsorption-type temperature sensor 1 having the above-described components will be described. Figs. 8 (a) to 8 (f) are views showing the assembly process of the magnet adsorption-type temperature sensor 1. Fig.

First, blood 13B, which is an engaged portion to be engaged with the engagement portion 11B3 of the lower main body case 11B, is formed on the thermocouple cable 13 having the thermocouple 13A at the tip end (step (a)). Further, the thermocouple 13A of the thermocouple cable 13 of the present embodiment uses a thin thermocouple wire having a line diameter of 100 mu m or less.

Next, the thermocouple 13A at the tip end of the thermocouple cable 13 is welded to the inner surface side of the dish-shaped contact member 14 (step (b)).

Next, the bottom surface portion 141 is inserted into the hole 11B1 through the lower body case 11B so that the bottom surface portion 141 of the dish-like contact member 14 to which the thermocouple cable 13 is connected is exposed , The blood 13B formed on the thermocouple cable 13 is engaged with the engagement portion 11B3 provided by the lower main body case 11B (step (c)). As a result, even when the thermocouple cable 13 is pulled out, it is suppressed that a force is applied to the joining portion of the thermocouple 13A and the dish type contact member 14.

Next, the magnet 12 is inserted into the upper main body case 11A (step (d)). As described above, the magnet 12 is held by the claw formed at the tip end of the engaging member 11A1.

Next, the upper main body case 11A and the lower main body case 11B, to which the respective members are attached in the above-described process, are fitted (step (e)). The claw formed at the tip end of the engaging member 11A2 of the upper main body case 11A engages with the reduced blood 11B4 of the lower main body case 11B as described above.

The distal end portion of the engaging member 11A1 of the upper body case 11A is brought into contact with the female portion 143 of the dish type contact member 14 when the upper body case 11A and the lower body case 11B are engaged, )do. As a result, contact between the dish-shaped contact member 14 and the magnet 12 is suppressed, and therefore, the engaging member 11A1 also functions as a gap-forming member.

The side wall 11A4 of the upper main body case 11A is formed so as to fill the cutout portion 11B5 of the lower main body case 11B when the upper main body case 11A and the lower main body case 11B are engaged with each other, And a space (opening) is formed at the lower end side of the thermocouple cable 13 so that the thermocouple cable 13 is drawn out. Thus, as shown in Fig. 8 (f), the thermocouple cable 13 is drawn out in the lateral direction of the main body case 11.

9 (a) and 9 (b) illustrate the drawing of the thermocouple cable 13, Fig. 9 (a) shows a case of pulling out the thermocouple cable 13 in the lateral direction, Fig. 9 Fig.

The drawing in the lateral direction (Fig. 9 (a)) is as described above. On the other hand, when the thermocouple cable 13 is to be pulled out in the direction of the top surface due to the processing of the thermocouple cable 13 at the time of mounting the object to be measured, the thermocouple cable 13 is attached to the cable holding portion 11A3 9 (b), the pull-out direction of the thermocouple cable 13 can be changed to the top surface direction.

As described above, according to the magnet adsorption-type temperature sensor 1 of the present embodiment, the number of parts is reduced, and assembly can be performed by an extremely simple operation.

That is, as apparent from comparison between Fig. 2 and Fig. 11, the magnet attracting temperature sensor 1 of the present embodiment is significantly reduced in the number of parts as compared with the conventional magnet attracting temperature sensor 100. [

The magnet adsorption type temperature sensor 1 according to the present embodiment can reduce the distance between the magnet 12 and the object to be measured. The member 105 can be made unnecessary (unnecessary). In addition, as described above, since each member can be properly held only by the upper main body case 11A and the lower main body case 11B basically, the number of parts can be reduced.

The magnet adsorption type temperature sensor 1 of the present embodiment can be assembled by an extremely simple operation as compared with the conventional magnet adsorption type temperature sensor 100. [ The thermocouple 102 is connected to the contact plate 101 on the plate spring by the welding W because the conventional magnet attracting temperature sensor 100 is difficult to weld after bending, 12 (a) and 12 (b)). However, according to the magnet adsorption-type temperature sensor 1 of the present embodiment, the dish contact member 14 is formed by press working The thermocouple 13A can be easily welded.

13 (a), it is necessary to mount the magnets 103 in the yoke member 105. In addition, in the conventional magnet attracting temperature sensor 100 shown in Fig. 13 (b) It is necessary to perform troublesome work of inserting both the contact plate 101 and the magnet 103 into the yoke member 105 and the troublesome operation is required also for the processing of the wire rod 108 connected to the thermocouple 102 However, according to the magnet adsorption-type temperature sensor 1 of the present embodiment, as described above, it is possible to easily assemble each member basically by merely inserting the members. The magnet adsorption type temperature sensor 1 may be provided by pushing back the claw portion of the engaging member 11A2 of the upper main body case 11A from the recessed blood 11B4 of the lower main body case 11B The thermocouple (thermocouple cable 13) and the like can be easily exchanged.

In addition, as described with reference to Fig. 9, it is possible to change the drawing direction of the thermocouple cable 13 in consideration of the processing of the thermocouple cable 13 at the time of mounting the object to be measured.

In addition, since the dish-shaped contact member 14, which is a member in contact with the object to be measured, has a dish shape, the area of stable contact with the object to be measured can be increased, and therefore accurate temperature measurement can be performed.

In the case of the contact plate 101 (Figs. 11 to 13) on the plate spring of the related art, since the contact piece does not have a structure (independent structure) to be supported by the object itself, And it is necessary to provide another structure such as the guide 106 around the contact piece (this also leads to an increase in the number of parts) in order to obtain a stable contact. On the other hand, in the magnet adsorption-type temperature sensor 1 of the present embodiment, the contact piece is formed in the shape of a dish having independent structural features (the dish contact member 14), thereby increasing the area stably contacting the measurement object Accurate temperature measurement can be performed while reducing the number of parts.

In the magnet adsorption-type temperature sensor 1 of the present embodiment, since a thin thermocouple wire (? 100 mu m or less) is used for the thermocouple 13A, the amount of heat radiation from the thermocouple 13A can be suppressed. Accordingly, the function of lowering the temperature of the measurement object can be further reduced, and accurate temperature measurement becomes possible.

The accuracy (accuracy) of the temperature measurement can be increased in a phase-parallel manner by using the above-mentioned contact piece in a dish shape and using a thin thermocouple wire (φ 100 μm or less). That is, the dish-like contact piece structure can receive heat from the object to be measured in a large area, and accordingly, the dish-shaped contact member 14 itself can be brought close to the temperature of the object to be measured. When the heat is converted into electricity by the thermocouple 13A but is released from the thermocouple 13A itself, the temperature of the object to be measured is lowered to lower the degree of temperature measurement. However, by using a thin thermocouple wire, have.

By combining these two functions, heat can be absorbed and heat dissipation can be reduced, so that the temperature of the object to be measured can be grasped more accurately.

In the present embodiment, the basic case of the main body case is described as being cylindrical, but the present invention is not limited thereto. For example, the basic mode may be a quadrangular prism. Similarly, the dish-shaped contact member is not limited to a circular shape but may be, for example, a quadrangular shape.

In this embodiment, the magnet is held in the upper main body case, but the magnet may be held in the lower main body case.

In addition, in the present embodiment, the main body case is divided into upper and lower parts, that is, the upper and lower main body cases are provided, but the present invention is not limited to this, and for example, it may be divided left and right.

In the present embodiment, the engaging member of the upper main body case serves also as a gap forming member, but it is also possible to form the gap forming member as a separate member, for example, A spacer or the like may be disposed between the substrate 12 and the substrate. The gap-defining member is formed of a heat insulating member.

In the present embodiment, the cable holding portion is described as changing the drawing direction of the thermocouple cable to the top surface direction. However, the present invention is not limited to this, and the direction of drawing out the thermocouple cable may be changed or held in a direction other than the top surface direction .

As shown in Fig. 10, the tab-like contact member may be provided with a cut-in portion 143a in the female portion 143 for facilitating press working or the like. Further, it is also possible to form the side portion 142 in a further infiltrated shape.

1 ... Magnet adsorption type temperature sensor
11 ... body case
11A ... upper body case
11A1 ... Engagement member (gap forming member)
11A2 ... engagement member
11A3 ... cable holding portion
11B ... Lower main body case
11B1 ... hole (hole)
11B2 ... bottom edge
11B3 ... engaging portion
11B4 ... Sense of blood (fitting hole)
11B5 ... notch portion
12 ... magnets
13 ... thermocouple cable
13A ... thermocouple (thermocouple)
13B ... Bore (hole) (engaged part)
14 ... dish contact member
141 ... bottom face portion
142 ... side portion
143 ... brim portion

Claims (7)

1. A magnet adsorption type temperature sensor which is attracted to a measurement object by a magnetic force,
A dish-shaped contact member for contacting the measurement object,
A thermocouple cable to which a thermocouple portion is connected to the inner surface side of the dish-
The magnet,
Wherein the magnet is held (held), and at the same time, the bottom surface of the dish-like contact member is exposed (exposed) so as to hold the flange portion of the dish-
And a temperature sensor for detecting the temperature of the magnet. The method according to claim 1,
And a gap-forming member for forming a predetermined gap between the dish-shaped contact member and the magnet. The method according to claim 1,
Wherein,
A lower main body case for holding the dish type contact member so that a bottom face of the dish type contact member is exposed,
An upper main body case which is engaged with the lower main body case and holds the magnet inside the lower main body case,
And a temperature sensor for detecting the temperature of the magnet. The method of claim 3,
In the upper main body case,
An interval forming member,
And an engaging member
Is formed on the surface of the magnet. The method according to claim 1,
Wherein an engaging portion is formed on the thermocouple cable and an engaging portion engaging with the engaging portion is formed on either the main body case or the dish-shaped contact member. 6. The method according to any one of claims 1 to 5,
Wherein an opening for withdrawing the thermocouple cable is formed in the main body case,
Wherein the main body case is provided with a cable holding portion for changing the drawing direction of the drawn-out thermocouple cable. 1. A manufacturing method of a magnet adsorption type temperature sensor which is attracted by a magnetic force to a measurement object,
Connecting the thermocouple portion of the thermocouple cable to the inner surface side of the dish-shaped contact member,
The lower body case is mounted on the lower body case so that the bottom surface of the dish-shaped contact member to which the thermocouple cable is connected is lengthened, the lower body case holds the flange portion of the dish- A step of engaging an engaging portion of the thermocouple cable with an engaging portion provided with the thermocouple cable,
A step of inserting (inserting) a magnet into the upper main body case,
An upper main body case housing the magnet, a step of fitting the lower main body case
Wherein the temperature of the magnetically attracted temperature sensor is less than the temperature of the magnet.

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