JPH0425631A - Damper device - Google Patents

Abstract

PURPOSE:To enable a proper control of damper gear torque value by fixing one end of shape memory alloy controlled in its energization by means of a temperature seneor while connecting the other end to a movable damper device main body, and moving the main body to the damper gear through deformation of the main body to the low and high temperature side of the shape memory alloy. CONSTITUTION:A damper device is normally monitored in its circumferential ambient temperature. At the time of low temperature at which the viscousity of grease oil 15 increases, a shape memory alloy 16 shrinks to separate a damper device main body from a damper gear 14 thereby reducing the contact resistance area between the body 11 and the gear 14. As a result, a damper gear torque value decreases as the viscousity of gease oil 15 increases. When a circumferential ambient temperature moves from the low temperature to the normal temperature, the sensor senses it to supply current to the alloy 16 for heat emission, and thereby the shape is resumed to the shape at the time of high temperature to increase the contact resistance area so as to increase the damper gear torque value as the viscousity of gease oil 15 is decreased thereby when the temperature is returned to the normal temperature.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a damper device for slowing down the rotational movement of a lid, door, drawer, etc. to obtain stable, high-quality movement.

BACKGROUND OF THE INVENTION Conventionally, this type of damper device has used viscous fluid, gas, etc. to be interposed between two objects connected in a rotational pair to slow and stabilize the operating speed when the two rotate relative to each other. It is used for. As the viscous fluid, grease oil is often used because it provides the most stable operation and provides a sufficient damping effect.

Hereinafter, a conventional damper device will be explained with reference to the drawings.

FIG. 5 shows an example of a damper device employed in a cassette tape ejecting mechanism of an audio device, and FIG. 6 is an exploded perspective view of the damper device. In these figures, 1 is a damper device main body, 2 is a damper gear rotatably fitted to the fixed shaft 1a of the damper device main body 1,
3 is a cassette holder, and 4 is a sector gear that is formed integrally with the cassette holder 3 and meshes with the damper gear 2. 5 is a cabinet of the audio device; 6 is a mechanism support plate that supports a mechanism for recording and reproducing a cassette tape; 7 is a cassette tape; 8 is a cassette holder that stores the driving force for opening the cassette holder 3 from the cabinet 5; An open spring, 9, is a grease oil that keeps the damper gear 2 viscous in the damper device body 1, 1
0 is a rotation shaft that holds the cassette holder open spring 8 and is the rotation center when the cassette holder 3 is opened and closed.

Next, the operation of the conventional example will be explained. First, when the lock (not shown) of the cassette holder 3 is released,
Due to the spring force of the cassette holder open spring 8, the cassette holder 3 begins to open around the rotating shaft 10. At this time,
Sector gear 4 integrally formed with cassette holder 3
tries to turn damper gear 2, but damper gear 2
Because of the viscous resistance of the grease oil 9 interposed between the damper device main body 1, a rotational resistance torque is added to the cassette holder 3. Due to this rotational resistance torque, the cassette holder 3 opens at a low speed and opens by a predetermined angular amount. Afterwards, the cassette tape 7 can be taken out from the cassette holder 3.

Problems to be Solved by the Invention However, in the conventional damper device, as shown in FIG. As the viscous resistance increases and the damper gear torque value generated by the damper device increases, the opening speed of the cassette holder 3 decreases significantly, and sometimes the cassette holder 3
Sometimes it wouldn't open. As a solution to this problem, some devices increase the spring force of the cassette holder open spring 8, but this conversely reduces the damper gear torque value at room temperature and increases the opening speed of the cassette holder 3. There was a problem that the opening operation position of the cassette holder 3 was impaired.

The present invention solves these conventional problems, and aims to provide a damper device that can always obtain an appropriate damper gear torque value in response to changes in ambient temperature.

Means for Solving the Problems In order to achieve the above object, the present invention attaches a shape memory member to either the damper device main body or the damper gear, and when the viscosity of the viscous fluid becomes high at low temperatures, the shape memory member is The damper device main body is relatively separated from the damper gear by the side deformation, thereby reducing the contact resistance area between the two.

The present invention also has a shape memory alloy whose energization is controlled by a temperature sensor, one end of this shape memory alloy is fixed and the other end is connected to a movable damper device main body, and this damper device main body is connected to a shape memory alloy. By moving the alloy relative to the damper gear by deforming the alloy on the low temperature side and the high temperature side, the contact resistance area with the damper gear is changed to appropriately control the damper gear torque value.

Effects According to the present invention, the contact resistance area between the damper device main body and the damper gear is reduced at low temperatures when the viscosity of the viscous fluid increases, so that the viscous resistance of the viscous fluid, which increases at low temperatures, is offset. A necessary and appropriate damper gear torque value can be obtained.

The present invention also provides that when the ambient temperature falls below the transformation temperature of the shape memory alloy on the low temperature side, the damper device main body separates from the damper gear due to the deformation of the shape memory alloy, reducing the contact resistance area between the two. The damper gear torque value can be reduced by the increased viscosity of the viscous fluid. In addition, when the ambient temperature rises from a low temperature and exceeds a set temperature, the shape memory alloy is energized by a signal from the temperature sensor and generates heat due to its own electrical resistance, causing the shape memory alloy to exceed the transformation temperature on the high temperature side. When this happens, the shape returns to its original state and increases the contact resistance area between the damper device body and the damper gear, so the viscosity of the viscous fluid decreases when the temperature reaches room temperature (the damper gear torque value decreases accordingly). In this way, the damper gear torque value of the damper device can always be maintained at an appropriate value regardless of changes in the ambient environment temperature.

EXAMPLE Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a sectional view showing the configuration of a cassette tape ejecting mechanism using a damper device according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the cassette tape ejecting mechanism. In these figures, 11 is a damper device main body, and one side thereof has a central axis 11a, an annular groove 11b around it, a large diameter part 11c, and a small diameter part 11 (I
and a hook lle on the other side. 1
Reference numeral 2 designates an audio device cabinet, and one side thereof is provided with a cylindrical portion 12a that loosely fits into the large diameter portion 11C of the damper device main body 11. 13 is cabinet 1
2, and a guide hole 11f provided in the damper device main body 11 is loosely fitted into this guide pin 13. Reference numeral 14 denotes a damper gear, which has an outer cylindrical portion 14a having the same outer diameter as the large diameter portion 11c of the damper device main body 11 and loosely fits into the small diameter portion lid, and an annular groove portion of the damper device main body 11 on one side thereof. 1
Inner cylindrical portion 1 that enters 1b and loosely fits into central shaft 11a
4b, and a gear portion 14c on the other side. 15 is the damper device main body 11 and the cabinet 1
This is grease oil filled in the gap between the damper gear 2 and the damper gear 14.

16 is a shape memory alloy formed into a coil spring shape and memorized to a certain length on the low temperature side and the high temperature side,
One end thereof is locked to a hook lle of the damper device main body 11. 17 is a guide block for accommodating the shape memory alloy 16 and guiding its movement. 18 is a cabinet 12 for locking the other end of the shape memory alloy 16;
This is a locking pin that protrudes from. 19 is shape memory alloy 16
is a power supply connected via a switch 20 to both ends of the
21 is a temperature sensor that measures the ambient temperature of this damper device. 22 is a control circuit connected to the temperature sensor 21, and 23 is a solenoid connected to the control circuit 22 to drive the switch 20. These solenoids 2
3 and the switch 20 may be replaced with an electromagnetic relay, a reed relay, or the like. In addition, the temperature sensor 21
and switch 20 can also be constructed of bimetallic switches.

Reference numeral 24 designates a cassette holder similar to the conventional cassette holder shown in FIGS. 5 and 6, and has a rotating shaft 25 at the bottom and a damper gear 14 on the side.
It has a sector gear 26 that meshes with. The cassette holder 24 is biased to rotate in the opening direction by a cassette holder open spring 27 inserted into the rotating shaft 25.

Next, the operation of the above embodiment will be explained. The ambient temperature of this damper device is constantly monitored by a temperature sensor 21, and if the transformation a temperature on the low temperature side of the shape memory alloy 16 is TI and the transformation temperature on the high temperature side is T2, the ambient environment temperature is below T1. The solenoid 23 and the switch 20 do not operate until the temperature decreases to 0, and the shape memory alloy 16 is maintained at the length Ll at the time of high temperature memory, as shown in FIG.

In this high temperature state, the contact resistance area between the damper device main body 11 and the damper gear 14 is the largest, and the damper gear torque value due to the viscous resistance of the grease oil 15 is also relatively large. Therefore, when the stopper of the cassette holder 24 is removed and the cassette holder 24 is opened by the rotation biasing force of the cassette holder open spring 27, the sector gear 26 receives a relatively large torque from the damper gear 14, slowing down its rotation, and the cassette holder 24 will open slowly.

When the ambient temperature falls below T1, the shape memory alloy 16 reaches the transformation temperature T1 on the low temperature side, so as shown in FIG. 3, it shrinks to the length L2 on the low temperature side where the shape is memorized. In this low temperature state, the damper device main body 11 is pulled by the shape memory alloy 16, so the contact resistance area between the damper device main body 11 and the damper gear 14 becomes small, and the damper gear torque value due to the viscous resistance of the grease oil 15 also becomes small. Become.

When the ambient temperature falls below T1, the viscosity of the grease oil 15 usually increases, the damper gear torque value increases as shown by the chain line 28 in FIG. 4, and the opening speed of the cassette holder 24 becomes slower than at room temperature. However, in this embodiment, by reducing the contact resistance area between the damper device main body 11 and the damper gear 14, the damper gear torque value is reduced to the normal value as shown by the solid line 29 in FIG. The opening speed of the cassette holder 24 is kept at the same speed as in the room temperature state.

When the ambient temperature rises again from T1 to T2, the temperature sensor 21 detects this and turns on the solenoid 23 via the control circuit 22, turning on the switch 20. As a result, a current flows from the power source 19 to the shape memory alloy 16,
The shape memory alloy 16 generates heat due to its own electrical resistance,
When the transformation temperature T2 on the high temperature side is reached, the length L1 stored on the high temperature side is returned, and the damper device main body 11 returns to the position shown in FIG. 1 again. After a certain period of time has elapsed after the ambient temperature reaches the transformation temperature T2, the control circuit 22 turns off the retsunoid 23, turns off the switch 20, and cuts off the current flowing through the shape memory alloy 16.

As described above, according to the embodiment, at low temperatures when the viscosity of the grease oil 15 increases, the shape memory alloy 16 shrinks and separates the damper device main body 11 from the damper gear 14, reducing the contact resistance area between the two. Grease oil 15
The damper gear torque value decreases to the extent that the viscosity of 21 detects this, energizes the shape memory alloy 16 to generate heat, and returns the shape to the memory shape on the high temperature side.
The contact resistance area between the damper gear 14 and the damper gear 14 becomes larger, and the damper gear torque value is increased by the amount that the viscosity of the grease oil 15 becomes lower due to the room temperature. In this way,
The operating speed of the cassette holder 24 can always be kept appropriate regardless of changes in ambient temperature.

In the above embodiment, the shape memory alloy itself was energized to generate heat in order to return the shape memory alloy to its memorized shape on the high temperature side. For example, the guide block 17 may be energized to generate heat, or The shape memory alloy 16 may be heated by a built-in heater.

In such cases, shape memory polymers can be used instead of shape memory alloys.

Further, depending on the device to which the damper device of the present invention is applied, a shape memory member is provided on the damper gear side, and the damper gear is moved relative to the damper device body by deformation of the shape memory member to adjust the damper gear torque value. You can.

Effects of the Invention As described above, according to the present invention, a shape memory member is attached to either the damper device main body or the damper gear, and when the viscosity of the viscous fluid increases at low temperatures, the damper is deformed on the low temperature side of the shape memory member. The device body is relatively separated from the damper gear to reduce the contact resistance area between the two, so it is not affected by changes in the ambient environment temperature.
An appropriate damper gear torque value can always be obtained, and a high-quality damper device with stable operation can be realized.

Further, according to the present invention, a shape memory alloy is used as a shape memory member, and deformation from a low temperature side to a high temperature side is performed by energizing the shape memory alloy to generate heat based on a signal from a temperature sensor. The deformation operation can be performed reliably with a simple configuration.

[Brief explanation of drawings]

FIG. 1 is a sectional view of a cassette tape ejecting mechanism using an embodiment of the present invention, and FIG.
FIG. 3 is an exploded perspective view of the dispensing mechanism; FIG. 3 is a sectional view showing the operating state in the same embodiment; FIG. 4 is a graph showing the relationship between the damper gear torque value and the ambient temperature in the same embodiment;
The figure is a sectional view of a conventional cassette tape ejecting mechanism.
The figure is an exploded perspective view of a damper device used in a conventional cassette tape ejecting mechanism, and FIG. 7 is a graph showing the relationship of the damper gear torque value to the ambient temperature of the conventional damper device. DESCRIPTION OF SYMBOLS 11... Damper device main body, 12... Cabinet, 13... Guide pin, 14... Damper gear, 1
5... Grease oil, 16... Shape memory alloy, 17
... Guide block, 18 ... Locking pin, 19 ...
・Power supply, 20 switch, 21...temperature sensor, 22・
... Control circuit, 23... Solenoid, 24... Cassette holder, 25... Rotating shaft, 26... Sector gear, 27... Cassette holder open spring. Name of agent Patent attorney Hiroshi Masaaki Kura I/I41 Figure 3 Figure 4 Ti 72 Temperature ('C) -= Figure 5 2...5'' shield key 3...Cassette halter 4 ... Sector carrier 5 ... Cabinet 6 ... Mechanism support plate 7 ... Cassette tape 8 ... Cassette holder orb spring #!7 Figure ○ +o 20 Temperature ('C) -1)

Claims (3)

[Claims] (1) A damper device having a damper gear rotatably supported by a damper device main body, and slowing the rotational speed of the damper gear by viscous resistance of viscous fluid interposed between the damper device main body and the damper gear, wherein the damper device A shape memory member is attached to either the device main body or the damper gear, and at low temperatures when the viscosity of the viscous fluid increases, the damper device main body is relatively separated from the damper gear by deformation on the low temperature side of the shape memory member, and the damper device main body is relatively separated from the damper gear. A damper device characterized by reducing the contact resistance area between. (2) A damper device having a damper gear rotatably supported by a damper device main body, and slowing the rotational speed of the damper gear by viscous resistance of viscous fluid interposed between the damper device main body and the damper gear, wherein the damper device A shape memory alloy is attached to the device body, and at low temperatures when the viscosity of the viscous fluid increases, the shape memory alloy is deformed on the low temperature side to separate the damper device body from the damper gear and reduce the contact resistance area between the two. ,
At room temperature, when the viscosity of the viscous fluid is relatively low, the shape memory alloy is deformed on the high temperature side to bring the damper device body closer to the damper gear to increase the contact resistance area between the two, thereby increasing the temperature from the low temperature to the high temperature. A damper device that deforms the shape memory alloy by energizing the shape memory alloy to generate heat based on a signal from a temperature sensor that detects the ambient temperature. (3) The damper device according to claim 1 or 2, wherein the viscous fluid is grease oil.