JP5863552B2 - Thermo actuator - Google Patents

Description

  The present invention relates to a thermoactuator in which a rod advances and retreats by expansion and contraction of wax.

  There is known a thermoactuator in which a rod is advanced and retracted by expansion and contraction of wax accommodated in a case (see, for example, Patent Document 1 FIGS. 4 and 5).

Patent Document 1 will be described with reference to FIG.
As shown in FIG. 11A, the thermoactuator 200 includes a guide member 201, a rod 202 guided by the guide member 201 and advanced and retreated by wax, and a portion of the rod 202 exposed from the guide member 201. And boots 203 covering.

  By covering the portion of the rod 202 exposed from the guide member 201 with the boot 203, it is possible to prevent dust from being caught between the guide member 201 and the rod 202.

The boot 203 has a base end 203 a fitted in the groove 201 a of the guide member 201. Further, a claw portion 201b is formed on the periphery of the groove portion 201a of the guide member 201.
As shown in FIG. 11 (b), the boot 203 is attached by bending the claw portion 201 b toward the base end portion 203 a of the boot 203.

  According to the thermoactuator 200, since the process of bending the base end portion 203a is indispensable, the number of steps is increased.

  It is desired to provide a thermoactuator assembly technique that can omit the bending process.

Japanese Patent Publication No.8-111953

  It is an object of the present invention to provide a thermoactuator assembling technique that can omit a bending process.

The invention according to claim 1 includes a case as a main body, a wax storage portion attached to one end of the case and storing wax, and the case stored in the case and expanded in excess of a predetermined temperature. A piston that moves forward toward the other end, a rod that is connected to the piston and that has a part of the tip exposed from the case, a boot that covers the exposed portion of the rod and that has flexibility, and a case In a thermoactuator comprising a return spring that is housed and urges the rod in a backward direction, a sleeve that supports the rod to be able to advance and retract is attached to the other end of the case, and the outer periphery of the sleeve is connected to the central axis of the rod. When the sleeve groove that is recessed toward the bottom is formed and the rod is at the rear end position, the rod is exposed to the portion exposed from the case. A rod groove part that is recessed toward the central axis of the boot is formed, a sleeve fitting part that fits into the sleeve groove part is formed at one end of the boot, and a rod that fits into the rod groove part at the other end of the boot A fitting portion is formed, the sleeve fitting portion is fitted into the sleeve groove portion, the outer periphery is pressed by the case, the rod fitting portion is fitted into the rod groove portion, and the outer periphery is attached to the rod. Pressed by the cap member ,
In the case, a guide portion is formed so as to surround the piston so as to guide the forward / backward direction of the piston,
On the outer periphery of the guide portion, a flat portion having a flat surface shape is formed,
The rod has a cylindrical retainer portion that surrounds the outer periphery of the guide portion,
A pin that is slidably contacted with the flat portion is attached to the retainer portion .

According to a second aspect of the present invention, there is provided a case as a main body, a wax storage portion attached to one end of the case and storing wax, and the case stored in the case and expanded in excess of a predetermined temperature. A piston that moves forward toward the other end, a rod that is connected to the piston and that has a part of the tip exposed from the case, a boot that covers the exposed portion of the rod and that has flexibility, and a case In a thermoactuator comprising a return spring that is housed and urges the rod in a backward direction, a sleeve that supports the rod to be able to advance and retract is attached to the other end of the case, and the outer periphery of the sleeve is connected to the central axis of the rod. When the sleeve groove that is recessed toward the bottom is formed and the rod is at the rear end position, the rod is exposed to the portion exposed from the case. A rod groove part that is recessed toward the central axis of the boot is formed, a sleeve fitting part that fits into the sleeve groove part is formed at one end of the boot, and a rod that fits into the rod groove part at the other end of the boot A fitting portion is formed, the sleeve fitting portion is fitted into the sleeve groove portion, the outer periphery is pressed by the case, the rod fitting portion is fitted into the rod groove portion, and the outer periphery is attached to the rod. Pressed by the cap member,
In the case, a guide portion is formed so as to surround the piston so as to guide the forward / backward direction of the piston,
The rod has a cylindrical retainer portion that surrounds the outer periphery of the guide portion,
The central axis of the retainer portion coincides with the central axis of the piston, and the central axis of the guide portion is eccentric.
The invention according to claim 3 is characterized in that the sleeve is formed with a communication hole that communicates the inside of the case with the inside of the boot.

In the invention according to claims 1 and 2 , the sleeve fitting portion is formed at one end of the boot. A sleeve groove is formed in the sleeve. The sleeve fitting portion is fitted in the sleeve groove portion, and the sleeve fitting portion is compressed by pressing the sleeve fitting portion by surrounding the sleeve with the case. That is, one end of the boot is fixed to the sleeve while being pressed against the sleeve by the case.

  The same applies to the rod fitting portion formed at the other end of the boot. That is, a rod fitting portion is formed at the other end of the boot. Moreover, the rod groove part is formed in the rod. The rod fitting portion is fitted into the rod groove portion, and the rod fitting portion is compressed by pressing the rod fitting portion by surrounding the rod with the cap member. That is, the other end of the boot is fixed to the rod while being pressed against the rod by the cap member.

  According to the present invention, it is not necessary to bend the tip of the case or the cap member when attaching the boot. Since the bending process is unnecessary, the number of man-hours can be reduced. Accordingly, it can be said that the thermoactuator can be easily assembled.

In particular, in the invention according to claim 1 , the rod has a cylindrical retainer portion that surrounds the outer periphery of the guide portion, and a pin that is slidably contacted with the flat portion of the guide portion is attached to the retainer portion. When the retainer part advances and retreats, the pin attached to the retainer part slides on the flat part of the guide part. By sliding on the flat portion, the retainer portion, that is, the rod is prevented from rotating. By preventing the rotation of the rod, the boot can be prevented from being twisted by the rod, and the life of the boot can be extended.

In particular, in the invention according to claim 2 , the central axis of the retainer part coincides with the central axis of the piston, and the central axis of the guide part is eccentric. The rotation center of the retainer portion provided on the outer periphery of the guide portion coincides with the central axis of the guide portion. On the other hand, the rod is supported by the sleeve so as to be able to advance and retreat. The sleeve prevents the rod from rotating when the retainer portion is to be rotated about the central axis of the guide portion. That is, since the central axis of the guide portion is eccentric, the sleeve serves to prevent the rod from rotating. By preventing the rotation of the rod, the boot can be prevented from being twisted by the rod, and the life of the boot can be extended.
In the invention according to claim 3, the sleeve is formed with a communication hole for communicating the inside of the case with the inside of the boot. As the rod advances, the boot extends with the rod. When extended, the air in the case can be taken into the boot through the communication hole. By taking the air in the case into the boot, the negative pressure generated when the boot is extended is suppressed. By suppressing the influence of the negative pressure, it is possible to extend the life of the boot.

1 is a cross-sectional view of a thermoactuator according to Embodiment 1. FIG. FIG. 2 is an enlarged view of part 2 of FIG. 1. FIG. 3 is a sectional view taken along line 3-3 in FIG. 1. FIG. 4 is a sectional view taken along line 4-4 of FIG. It is a figure explaining the attachment method of the boot shown by FIG. It is a figure explaining the detail of the process of assembling the case shown by FIG. It is a figure explaining the detail of the process of assembling the cap member shown by FIG. It is a figure explaining the state to which the boot shown by FIG. 1 was attached. 6 is a cross-sectional view of a thermoactuator according to Embodiment 2. FIG. It is a figure explaining the effect | action of the thermo actuator shown by FIG. It is a figure explaining the basic composition of the conventional technology.

  Embodiments of the present invention will be described below with reference to the accompanying drawings. The drawings are viewed in the direction of the reference numerals.

First, an example in which the thermoactuator according to Embodiment 1 of the present invention is mounted on an exhaust heat recovery device will be described with reference to the drawings.
As shown in FIG. 1, the thermoactuator 10 includes a case 20 as a main body, a bottomed cylindrical wax storage portion 40 attached to one end 20a of the case 20 and storing a wax 41, and the wax storage. The medium container 50 is attached to the case 20 so as to surround the portion 40 and the medium is allowed to flow, and the wax 41 stored in the case 20 expands beyond a predetermined temperature toward the other end 20b of the case 20. A forwardly moving piston 60, a rod 70 connected to the piston 60 and partially exposed from the other end 20b of the case 20, and a flexible boot 90 that covers a portion of the rod 70 exposed from the case and has flexibility. A return spring 15 that is housed in the case 20 and urges the rod 70 in a backward direction, and a seat on which one end of the return spring 15 is seated. 6, a sleeve 80 which is movably supported rod 70 with is suppressed by the seat 16 and a cap member 18 for being attached to the tip of the rod 70.

  The case 20 includes two members, and a cylindrical cylinder portion 22 is attached to a support portion 21 that supports the wax storage portion 40.

  A guide portion 30 is formed integrally with the support portion 21 along the central axis PC, and a piston 60 is accommodated in a hole 31 formed in the inner periphery of the guide portion 30. That is, the advancing / retreating direction of the piston 60 is guided by the guide portion 30. Further, the central axes of the guide portion 30 and the rod 70 coincide with the central axis PC of the piston 60.

  At the tip of the cylinder portion 22, a mouth portion 24 having a narrowed diameter is formed. A sleeve 80 is fitted into the mouth portion 24.

  The wax 41 stored in the wax storage unit 40 has a property of expanding as the temperature rises. A diaphragm 42 that is deformed by expansion and contraction of the wax 41 is attached so as to close the wax storage unit 40.

  The hole 31 is formed to have a diameter substantially the same as the inner diameter of the wax storage portion 40 at a portion where the diaphragm 42 is disposed. The hole 31 is continuously reduced in diameter from the portion where the diaphragm 42 is disposed toward the tip, and is reduced to a diameter substantially the same as the outer diameter of the piston 60. The hole 31 that has been reduced in diameter to approximately the same diameter as the outer diameter of the piston 60 is formed linearly toward the tip while maintaining the same diameter.

  Inside the hole 31, a region between the wax accommodating portion 40 and the piston 60 is filled with a fluid 43 for pushing the piston 60 when the diaphragm 42 is deformed.

  The medium container 50 is connected to the heat recovery device of the exhaust heat recovery device. A medium (for example, cooling water) that has passed through the heat recovery device is introduced from the medium introduction port 51 and discharged from the medium discharge port 52. When flowing in the medium container 50, the medium comes into contact with the outer periphery of the wax container 40, and the temperature of the medium is transmitted to the wax container 40.

  The piston 60 includes a rubber rubber piston 61 pushed by the fluid 43, a resin plate 62 formed integrally with the rubber piston 61, and a piston formed integrally with the plate 62 and pushing the rod 70. It consists of a main body 63. A seal member 64 for preventing leakage of the fluid 43 to the rod 70 side is attached to the piston body 63.

The rod 70 is configured such that a substantially cylindrical rod body 72 is supported by a retainer portion 71 that surrounds the guide portion 30.
The retainer portion 71 is formed with a flange portion 74 that protrudes toward the outer periphery, and this flange portion 74 serves as a seat for the return spring 15. The rod 70 is biased toward the right side of the drawing, that is, in the backward direction through the flange 74.

  A rod groove portion 75 that is recessed toward the central axis PC is formed at the tip of the rod body 72. That is, as shown in the drawing, when the rod 70 is at the rear end position (retreat limit), a rod groove portion 75 that is recessed toward the central axis PC is formed in a portion of the rod 70 exposed from the case 20. Has been.

  The sleeve 80 is a member formed in a hat shape in sectional view, and supports the rod main body 72 so as to be able to advance and retreat by a rod support hole 81 opened along the central axis PC. A sleeve groove 82 is formed at the tip of the sleeve 80 so as to be recessed toward the central axis PC. Furthermore, although mentioned later for details, the communicating hole 83 which connects the inside of case 20 and the inside of boot 90 is formed along the axial direction of central axis PC.

When the thermoactuator 10 is mounted on a device other than the exhaust heat recovery device, the outer periphery of the wax storage unit 40 can be surrounded by a heater instead of the medium container 50. That is, the thermoactuator 10 according to the present invention is not limited to one that operates according to the temperature of the medium.
Details of the boot 90 will be described with reference to FIG.

  As shown in FIG. 2, a sleeve fitting portion 91 to be fitted to the sleeve groove portion 82 is formed at one end (right side of the drawing) of the rubber boot 90, and the rod groove portion 75 is formed at the other end of the boot 90. A rod fitting portion 92 to be fitted to is formed. The sleeve fitting portion 91 is fitted into the sleeve groove portion 82 and the outer periphery thereof is pressed by the mouth portion 24 of the case 20. The rod fitting portion 92 is fitted into the rod groove portion 75 and the outer periphery is pressed by the cap member 18.

  A sleeve fitting portion 91 is formed at one end of the boot 90. A sleeve groove 82 is formed in the sleeve 80. The sleeve fitting portion 91 is fitted in the sleeve groove portion 82, and the sleeve fitting portion 91 is compressed and pressed against the sleeve groove portion 82 by surrounding the sleeve 80 with the case 20. That is, one end of the boot 90 is fixed to the sleeve 80 while being pressed against the sleeve 80 by the case 20.

  In addition, the configuration in which the sleeve fitting portion 91 is sandwiched between the sleeve groove portion 82 and the case 20 can prevent the boot 90 from coming off in the circumferential direction (outer peripheral side).

  The same applies to the rod fitting portion 92 formed at the other end of the boot 90. That is, a rod fitting portion 92 is formed at the other end of the boot 90. Further, a rod groove portion 75 is formed in the rod 70. The rod fitting portion 92 is fitted in the rod groove portion 75, and the rod 70 is surrounded by the cap member 18, so that the rod fitting portion 92 is compressed and pressed to the rod groove portion 75. That is, the other end of the boot 90 is fixed to the rod 70 while being pressed against the rod 70 by the cap member 18.

  In addition, the configuration in which the rod fitting portion 92 is sandwiched between the rod groove portion 75 and the cap member 18 can prevent the boot 90 from coming off in the circumferential direction (outer circumferential side).

  According to the present invention, it is not necessary to bend the tip of the case 20 or the cap member 18 when attaching the boot 90. Since the bending process is unnecessary, the number of man-hours can be reduced. Therefore, it can be said that the thermoactuator 10 can be easily assembled.

For the boot 90, an arbitrary material having flexibility such as soft resin can be selected in addition to rubber.
In FIG. 3, the communication hole (FIG. 1, reference numeral 83) will be described in detail.

  As shown in FIG. 3, the communication hole 83 has a substantially semicircular shape, and is formed in the inner sleeve of a plurality (three in this embodiment) of the sleeve 80 so as to face the outer peripheral surface of the rod 70. Each communication hole 83 is formed at equal intervals with respect to the rod 70.

Returning to FIG. 1, the communication hole 83 is formed so as to face the outer peripheral surface of the rod 70. By forming the communication hole 83 in the vicinity of the rod 70, the sleeve groove portion 82 can be formed in the vicinity of the rod support hole 81. By forming the sleeve groove portion 82 in the vicinity of the rod support hole 81, the outer diameter of the sleeve 80 can be reduced, and the sleeve 80 can be reduced in size. By miniaturizing the sleeve 80, the thermoactuator 10 as a whole can be miniaturized.
Details of the guide portion (FIG. 1, reference numeral 30) and the retainer (FIG. 1, reference numeral 71) will be described with reference to FIG.

  As shown in FIG. 4, the outer peripheral surface of the guide portion 30 has flat flat portions 34 and 34 formed opposite to each other, and an arc shape formed so as to connect the flat portions 34 and 34. Arc portions 35, 35.

  Cylindrical pins 101 and 101 are inserted into pin insertion holes 76 and 76 formed in the retainer portion 71. The pins 101 and 101 are in contact with the flat portions 34 and 34, respectively. Half of the outer periphery of the pins 101, 101 is inserted into the pin insertion holes 76, 76.

When the retainer unit 71 moves forward or backward in the drawing front / back direction, the pins 101 and 101 move together with the retainer unit 71. When moving, the pins 101 and 101 slide on the flat portions 34 and 34. When a force is applied to the retainer portion 71 in the rotation direction, the pins 101 and 101 are sandwiched between the retainer portion 71 and the flat portions 34 and 34 to prevent the retainer portion 71 from rotating. The retainer portion 71, that is, the rod is prevented from rotating. By preventing the rotation of the rod 70, the boot (FIG. 1, reference numeral 90) is prevented from being twisted by the rod 70, and the life of the boot can be extended.
The operation of the thermoactuator 10 will be described with reference to FIG.

  Returning to FIG. 1, by operating the internal combustion engine, the medium that has passed through the heat exchanger of the exhaust heat recovery apparatus is gradually warmed by the exhaust gas. That is, the temperature of the medium introduced from the medium introduction port 51 gradually increases. The temperature of the medium is transmitted to the wax 41 through the wax storage unit 40 and causes the wax 41 to expand. As the wax 41 expands, the diaphragm 42 is deformed so as to protrude toward the left side of the drawing. When the diaphragm 42 is deformed, the fluid 43 is pushed, and the fluid 43 pushes the piston 60. The rod 70 moves forward against the force of the return spring 15 by being pushed by the piston 60. As the rod 70 advances, the boot 90 extends.

  As the rod 70 moves forward, the boot 90 extends together with the rod 70. When extended, the air in the case 20 can be taken into the boot 90 through the communication hole 83. By taking the air in the case 20 into the boot 90, the influence of the negative pressure generated when the boot 90 is extended is suppressed. By suppressing the influence of the negative pressure, the life of the boot 90 can be extended.

On the other hand, when the internal combustion engine is stopped, the temperature of the medium that has passed through the heat exchanger gradually decreases. As the temperature of the medium decreases, the wax 41 contracts. As the wax 41 contracts, the rod 70 is retracted by the force of the return spring 15. As the rod 70 moves backward, the piston 60 also moves backward, and the diaphragm 42 also returns to its original shape. Further, the boot 90 is contracted by the retraction of the rod 70.
An example of a method for attaching the boot 90 will be described with reference to FIG.

  As shown in FIG. 5A, first, the sleeve fitting portion 91 is fitted into the sleeve groove portion 82 and the rod fitting portion 92 is fitted into the rod groove portion 75.

  As shown in FIG. 5B, in the state in which the sleeve fitting portion 91 is fitted in the sleeve groove portion 82, a gap of length Ta1 and Ta2 are provided between the sleeve fitting portion 91 and the sleeve groove portion 82. There is a gap. That is, there is a total gap of Ta1 + Ta2 between the sleeve fitting portion 91 and the sleeve groove portion 82.

  Next, as shown in FIG. 5C, the case 20 is attached from the distal end side of the rod 70. The sleeve fitting portion 91 is pressed by the mouth portion 24.

  As shown in FIG. 6A, the base end portion 24a of the mouth portion 24 has a so-called round shape (arc shape), whereby the sleeve fitting portion 91 can be smoothly deformed. By deforming, the gap between the sleeve fitting portion 91 and the sleeve groove portion 82 becomes Tb. The gap between the sleeve fitting portion 91 and the sleeve groove portion 82 is reduced by the amount crushed by the mouth portion 24. That is, Tb <(Ta1 + Ta2).

  In addition, the base end part 24a of the opening part 24 can also be made into a taper shape etc. other than a round shape. That is, the sleeve fitting portion 91 can be formed in an arbitrary shape for easily deforming.

  As shown in FIG. 6B, when the case 20 is attached to the sleeve 80, there is almost no gap between the sleeve fitting portion 91 and the sleeve groove portion 82. That is, Tb≈0.

  As shown in FIG. 6C, when the case 20 is attached, the cap member 18 is attached from the distal end side of the rod 70. The rod fitting portion 92 is pressed by the tip end portion 18 a of the cap member 18.

  As shown in FIG. 7A, in the state in which the rod fitting portion 92 is fitted to the rod groove portion 75, a gap of length ta1 and ta2 are provided between the rod fitting portion 92 and the rod groove portion 75. There is a gap. That is, there is a total gap of ta1 + ta2 between the rod fitting portion 92 and the rod groove portion 75.

  As shown in FIG. 7B, the rod fitting portion 92 can be smoothly deformed by the tip portion 18 a of the cap member 18 having a tapered shape. By deforming, the gap between the rod fitting portion 92 and the rod groove portion 75 becomes tb. The gap between the rod fitting portion 92 and the rod groove portion 75 is reduced by the amount crushed by the cap member 18. That is, tb <(ta1 + ta2).

  In addition, the front-end | tip part 18a of the cap member 18 can also be made into a round shape other than a taper shape. That is, the rod fitting portion 92 can be formed in an arbitrary shape for easily deforming.

  As shown in FIG. 7C, when the cap member 18 is attached to the rod 70, there is almost no gap between the rod fitting portion 92 and the rod groove portion 75. That is, tb≈0.

As shown in FIG. 8, when the cap member 18 is attached, the work for attaching the boot 90 is completed.
Another embodiment of the thermoactuator will be described with reference to FIG.

Next, a second embodiment of the present invention will be described with reference to the drawings.
FIG. 9 shows a cross-sectional configuration of the thermoactuator of the second embodiment, corresponding to FIG.

  As shown in FIG. 9, in the thermoactuator 110, the central axis of the retainer portion 121 coincides with the central axis PC of the piston 60, and the central axis GC of the guide portion 130 is eccentric.

  The thermoactuator 110 configured as described above also achieves the predetermined effect of the present invention. In particular, the fact that the rotation of the rod 120 can be prevented will be described in detail with reference to FIG.

  As shown in FIG. 10B, the rotation center of the retainer portion 121 provided on the outer periphery of the guide portion 130 coincides with the central axis GC of the guide portion 130. That is, if the retainer unit 121 is rotated 180 °, the retainer unit 121 moves to the position indicated by the alternate long and short dash line.

  If the retainer portion 121 is rotated 180 degrees around the central axis GC of the guide portion 130, the rod 120 moves to the position indicated by the alternate long and short dash line, as shown in FIG.

  However, the rod 120 is supported by the sleeve 80 so as to be able to advance and retract. Therefore, the sleeve 80 prevents the rod 120 from rotating when an attempt is made to rotate the retainer portion (FIG. 10B, reference numeral 121) about the central axis GC of the guide portion 130. That is, the rod 120 to be rotated contacts the inner peripheral surface of the sleeve 80 and is prevented from rotating. By preventing the rod 120 from rotating, the boot (FIG. 9, reference numeral 90) is prevented from being twisted by the rod 120, and the life of the boot can be extended.

  Note that the thermoactuator according to the present invention has been described by taking as an example an attachment method in which a boot is fitted into a groove and then a case and a cap member are attached. However, it can also be assembled by pushing each fitting portion of the boot into a case or cap member that has been previously attached. Even in this case, the predetermined effect of the present invention can be obtained. That is, the assembly method of the thermoactuator is not limited to these methods, and other assembly methods may be employed.

  The thermoactuator of the present invention is suitable for an exhaust heat recovery device.

  DESCRIPTION OF SYMBOLS 10,110 ... Thermo actuator, 15 ... Return spring, 18 ... Cap member, 20 ... Case, 20a ... One end, 20b ... Other end, 30, 130 ... Guide part, 34 ... Flat part, 40 ... Wax storage part, 41 ... Wax, 60 ... piston, 70, 120 ... rod, 71, 121 ... retainer part, 75 ... rod groove part, 80 ... sleeve, 82 ... sleeve groove part, 83 ... communication hole, 90 ... boot, 91 ... sleeve fitting part, 92 ... Rod fitting part, 101 ... Pin, PC ... Central axis of piston, RC ... Central axis of rod.

Claims (3)

A case as a main body, a wax storage portion that is attached to one end of the case and stores wax, and the wax stored in the case expands beyond a predetermined temperature toward the other end of the case A piston that moves forward, a rod that is connected to the piston and has a part of the tip exposed from the case, a boot that covers the portion of the rod exposed from the case and has flexibility, and is housed in the case In a thermoactuator comprising a return spring that urges the rod in a backward direction,
The other end of the case is attached with a sleeve that supports the rod so as to advance and retreat,
A sleeve groove portion that is recessed toward the central axis of the rod is formed on the outer periphery of the sleeve,
When the rod is at the rear end position, a rod groove portion that is recessed toward the central axis of the rod is formed in a portion of the rod exposed from the case,
One end of the boot is formed with a sleeve fitting portion that is fitted into the sleeve groove portion, and the other end of the boot is formed with a rod fitting portion that is fitted into the rod groove portion,
The sleeve fitting portion is fitted into the sleeve groove portion, and the outer periphery is pressed by the case,
The rod fitting portion is fitted into the rod groove portion, and the outer periphery is pressed by a cap member attached to the rod ,
In the case, a guide portion for guiding the advancing and retreating direction of the piston is formed so as to surround the piston,
On the outer periphery of the guide portion, a flat portion having a flat surface shape is formed,
The rod has a cylindrical retainer portion that surrounds the outer periphery of the guide portion,
A thermoactuator characterized in that a pin that slides on the flat portion is attached to the retainer portion . A case as a main body, a wax storage portion that is attached to one end of the case and stores wax, and the wax stored in the case expands beyond a predetermined temperature toward the other end of the case A piston that moves forward, a rod that is connected to the piston and has a part of the tip exposed from the case, a boot that covers the portion of the rod exposed from the case and has flexibility, and is housed in the case In a thermoactuator comprising a return spring that urges the rod in a backward direction,
The other end of the case is attached with a sleeve that supports the rod so as to advance and retreat,
A sleeve groove portion that is recessed toward the central axis of the rod is formed on the outer periphery of the sleeve,
When the rod is at the rear end position, a rod groove portion that is recessed toward the central axis of the rod is formed in a portion of the rod exposed from the case,
One end of the boot is formed with a sleeve fitting portion that is fitted into the sleeve groove portion, and the other end of the boot is formed with a rod fitting portion that is fitted into the rod groove portion,
The sleeve fitting portion is fitted into the sleeve groove portion, and the outer periphery is pressed by the case,
The rod fitting portion is fitted into the rod groove portion, and the outer periphery is pressed by a cap member attached to the rod,
In the case, a guide portion for guiding the advancing and retreating direction of the piston is formed so as to surround the piston,
The rod has a cylindrical retainer portion that surrounds the outer periphery of the guide portion,
Wherein with respect to the central axis of the piston, with the central axis of I said retainer portion is consistent, features and to salicylate over mode actuator that central axis of the guide portion is eccentric. The thermoactuator according to claim 1 or 2, wherein a communication hole for communicating the inside of the case and the inside of the boot is formed in the sleeve.

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