KR100459956B1 - Temperature sensor control apparatus - Google Patents

Abstract

The present invention is a temperature memory control for controlling the temperature sensor to be a shape memory alloy to the first shape below the critical temperature and the second shape above the critical temperature to interlock with the semi-solid material to delay the return to the second shape Relates to a device.

Temperature sensor control device is located in the body 10, the body 10 and has a first shape below the critical temperature, the temperature sensor 20 which is a shape memory alloy which is exposed to the outside of the external critical temperature to form a second shape Before the control operation thereof, the temperature sensor 20 prevents the temperature sensing operation, and during the control operation of the control button 30 and the temperature sensor 20, which enables the operation of the temperature sensor 20, its return force To prevent damage to the refrigerated and frozen products by storing the semi-solid material in the fuselage 10 and checking the rotation of the movement display member 40 and the movement display member 40 rotated by the control button 30 so as to counter the The confirmation window 52 is displayed on the cover 10 is composed of cover 50 is covered on the body (10).

Description

TEMPERATURE SENSOR CONTROL APPARATUS}

The present invention relates to a temperature sensor device using a shape memory alloy (hereinafter referred to as a temperature sensor) having a first shape below a critical temperature and having a second shape that returns to its original shape when exposed to a temperature above the critical temperature. A temperature sensor control device for controlling to delay the return of the temperature sensor to the second shape in conjunction with the semi-solid material.

Usually, shape memory alloys are deformed at the yield point to give plastic deformation to a recognizable degree, and have a property of returning to the shape before deformation when the cause of deformation is lost. Shape memory alloys having such characteristics have been used in various industrial fields for various purposes until now, and in particular, the shape memory alloy can be formed into a predetermined characteristic element by heat-treating shape memory according to a predetermined purpose in relation to temperature. It is supposed to have

In addition to the Ti-Ni alloy, the shape memory alloy is a Fe-Pt, Ti-Si, Cu-Sn, Cu-Zn-Al alloy, etc., and mainly Ni-Ti alloys and Cu-Zn-Al alloys are used. The shape memory effect of these alloys is returned to the original shape and the second shape by inverse transformation above a certain temperature at which the shape becomes the first shape and the shape is stabilized by several percent plastic deformation at low temperature. Therefore, the manufacturing of shape memory alloy is divided into melting, drawing production and shape memory processing, which determine the characteristics of the alloy and the quality of the product, and the drawing work is the same as the general wire rod production work process. When manufacturing the shape, it is made by cold working according to the designed shape. After that, it is fixed with the jig and stored at a critical temperature of 400-550 캜.

Therefore, the shape memory alloy can be used as a functional material for sensors and actuators by using its deformable shape, or a fixed part such as a plate or a linear that is simply returned to its original shape outside a predetermined deformation temperature range. It is used to indicate the temperature display. A simple fixed part that displays these temperatures makes it easier to keep products such as frozen dairy products, frozen products such as frozen meat, and refrigerated foods such as milk, stored at predetermined temperatures, or exposed to critical temperatures during distribution. It is used to identify it.

In other words, US Pat. No. 5,735,607 discloses a shape memory alloy thawing sensor, wherein frozen frozen foods, such as blood or pharmaceutical products, as well as frozen or frozen foods are thawed for a short period of time, or exposed at or above a critical temperature. Even if it is present, it indicates that the product was in an unstable state, and permanently indicates the damage of the product due to the handling of the product in circulation or carelessness and malfunction of the cooling system, thereby preventing the inadvertent use of these products.

To this end, the sensor is provided with a shape memory alloy to change the shape of the sensor at or above the critical temperature, that is, the Austin temperature, so that it does not return to its original shape even in the Martin phase where the temperature becomes the initial temperature. In addition to the shape memory alloy, the sensor has a display surface; One or more members below the critical temperature, the first shape and the second temperature above the critical temperature, the second shape above the critical temperature, and then returning below the critical temperature even when the second temperature is below the critical temperature; The display surface does not appear when the member is provided on the member and has the first shape, but is composed of an indicator or the like such that the display surface has the second shape.

However, in the US patent, as the shape memory alloy member is deformed, a structure is added to prevent the member from returning to the first shape when the shape memory alloy member is deformed. Therefore, the structure is complicated and the deformation of the shape alloy itself is changed. Is not used. Therefore, these sensors are expensive and can be used for specific products and not for general products. In use, the sensor-mounted base must be properly attached to a product, such as a cumbersome process. The sensor also had to carefully check the status of the indicator.

In addition, the temperature sensor using a conventional shape memory alloy is sensitive to changes in the external temperature, and when the refrigerated distribution product is exposed to the outside temperature, the temperature sensor is operated within 1 hour. There was a difficulty. For example, this temperature sensor is applied to the milk surface within 1 hour of reaching 10 ° C to 30 ° C and within 30 minutes of reaching 10 ° C to 30 ° C at the top of the vaccine. . Therefore, in the general distribution process of refrigerated and frozen products, the temperature sensor may be treated as damaged regardless of the actual state of the product.

Due to this situation, the retail industry has a new temperature sensor device that can be operated in consideration of the non-refrigeration time required for loading a refrigerated vehicle and moving between vehicles, moving to a store refrigerator, and delivering it to homes and farms after production. Has developed a demand for easy to use.

The present invention has been invented in view of the above circumstances and the like, and the temperature sensor is operated to counter the restoration while using a restoring force which is exposed to the second shape and is reversely transformed to the second shape below the critical temperature. It is a main object to provide a temperature sensor control device.

Another object of the present invention is to control the operation of the temperature sensor to delay the restoration of the temperature sensor using the roughness and malleability of the semi-solid material to control the temperature sensor operation from the first shape to the second shape above the critical temperature below the critical temperature. It is to provide a sensor control device.

Still another object of the present invention is to allow the moving display member to receive and move the semi-solid material to be interlocked with the temperature sensor, so that the restoring force generated by the operation of the temperature sensor is formed on the illuminance and malleability of the semi-solid material and the outlet of the movable body. It is to provide a temperature sensor control device using a shape memory alloy to extend the operating time of the temperature sensor by adjusting according to the size of.

1 is an exploded perspective view showing a temperature sensor control device using a shape memory alloy according to an embodiment of the present invention,

Figure 2 is a perspective view showing the overall assembly of the temperature sensor control device using a shape memory alloy according to an embodiment of the present invention,

3 is a perspective view illustrating a temperature sensor control device using a shape memory alloy in which a control button and a movement display member are assembled into a fuselage according to an embodiment of the present invention;

4 is a cross-sectional view taken along line A-A of FIG.

Figure 5 is a perspective view showing an initial state of the temperature sensor control device using a shape memory alloy according to an embodiment of the present invention.

6A and 6B are perspective views illustrating a final operation state of a temperature sensor control apparatus using a shape memory alloy and a return state of a temperature sensor according to an embodiment of the present invention.

♠ Explanation of symbols on the main parts of the drawing ♠

10: body 20: temperature sensor

30: control button 40: movement display member

50: cover

In order to achieve these objects, the temperature sensor control apparatus of the present invention is located in the body 10, the body 10 and has a first shape below the critical temperature, and is exposed to the outside of the external critical temperature to become the second shape. Temperature sensor 20 made of a shape memory alloy, the control button 30 to prevent the temperature sensor operation of the temperature sensor 20 before its control and at the time of its control to enable the operation of the temperature sensor 20, the control button ( Rotation of the movement display member 40 and the movement display member 40 in which the semi-solid material is accommodated in the body 10 and rotated by the control button 30 so as to counter the return force thereof in association with 30. Confirmation window 52 is formed to confirm the damage of the refrigeration, frozen products to the outside to form a cover 50 is covered on the fuselage (10).

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view for explaining a temperature sensor control apparatus using a shape memory alloy according to an embodiment of the present invention.

Temperature sensor control device is located in the body 10, the body 10 and has a first shape below the critical temperature, the temperature sensor 20 which is a shape memory alloy which is exposed to the outside of the external critical temperature to form a second shape , The control button 30, which prevents the temperature sensing operation of the temperature sensor 20 before the operation control and enables the operation of the temperature sensor 20 at the time of operation control, against the return force thereof in conjunction with the temperature sensor 20 A confirmation window for storing a semi-solid material in the body 10 so as to confirm the damage of the refrigerated and frozen products to the outside by the rotation of the movement display member 40 and the movement display member 40 by the temperature sensor 20 A 52 is formed and consists of the lids 50 covered on the body 10.

The body 10 has an upper opening, and a display groove 11 is formed on one side of the wall portion around the circumference thereof. Since the circular support part 13 is formed in a concentric shape so that the lower part is open and has a predetermined height and width for supporting and accommodating the flange 33 integrally formed at the lower end of the control button 30 at the lower center of the body 10. A cavity 14 'is formed. In this cavity 14 ′, the engaging portion 14 extends from the top of the inner circumference of the circular support 13 to the concentric arc on the left and right in a radial line and protrudes integrally. As will be described in detail later, the engaging portion 14 is fitted with the flange 33 to support the control button 30, and in operation of the control button 30 the flange 33 is located in the cavity 14 ′. (See Figure 4). Fixing rod 12 is arranged slightly above the approximately center line of the body 10 and integrally fixed adjacent the wall portion to support one end of the temperature sensor 20. The accommodating portion 15 for storing the semi-solid material is formed in a fan shape on the wall portion 18 and the fixed rod 12 which are integrally formed around the arc-shaped circumference of the circular support portion 13 with respect to the arc-shaped wall portion of the body 10. It consists of the wall part 19 which adjoins the fuselage wall part and the wall part 18 to the same height, and the stopper 17 formed between the fuselage wall part and the arcuate wall part 18 on the opposite side of this wall part 19. As shown in FIG. On both side surfaces of the stopper 17, guide paths 16 are formed so as to be spaced apart from the fuselage wall portion and the arcuate wall portion 18.

The temperature sensor 20 includes a ring portion 21 for allowing one end to be fixed to the fixed rod 12 irrespective of the critical temperature, a straight portion 24 having a constant length straight line from the ring portion 21, and the other end thereof. Is composed of a conversion section 22 extending from the straight section 24 and bent at right angles to the ring section 21. That is, the temperature sensor 20 has a first shape having a bent portion below the critical temperature, and when exposed for a predetermined time above the threshold temperature, the conversion unit 22 of the first shape becomes a straight line of the second shape.

The control button 30 protrudes slightly over the cover 50 at the time of assembly. The control button 30 has a nurum portion 31 protruding from the lid 50 at the top, a length portion 32 extending from the nurum portion 31 to a vertical length, and the length portion 31 of the control portion 30. Concave portions 35 extending integrally from the circumference to the outside at the lower end and fitted with the engaging portion 14 of the circular support portion 13 are composed of flanges 33 formed at the lower end thereof. The flange 33 further has an extension 34 which extends integrally from directly underneath the recess 35 to contact the inner wall surface of the circular support 13 and adjoin the lower side of its engaging portion 14. (See Figure 4).

It is noted here that the extension part 34 may be formed by forming a placebo part integral with the coupling part 14 formed on the support part 13 of the body 10.

The movement display member 40 has a center of rotation for accommodating the length 31 of the control button 30 and a rotation shaft having cutouts 42 formed on both sides of its center line to accommodate the shoulder of the upper end of the flange 33. (41), a guide portion (43) extending horizontally from the circumference of the lower end of the rotary shaft (41) and positioned on the circular support (13) to position the length (24) of the temperature sensor (20), About 60-80 of the upper end of the rotating shaft 41⁰Extends adjacent to the upper end of the wall portion of the body 10 in an arc shape and extends downwardly from the position corresponding to the arc circumference of the guide portion 43 downwardly so that the temperature together with the outer wall portion of the rotating shaft 41 A display panel 45 having a support 44 for allowing the transducer 22 of the sensor 20 to be inserted and supported therein; The same size and shape as the inside of the housing 15 of the body 10, the upper and lower openings are formed, and one side wall is formed with an outlet 46 through which semi-solid material is discharged, and the other side is opened and the walls thereof are opened. The stopper 17 includes guide members 47 movably fitted to the guide path 16 on both sides and integrally coupled to the display panel 45.

The lid 50 seals the body 10 in which the temperature sensor 20, the control button 30, and the movement display member 40 are assembled therein, and the semi-solid material is accommodated in the accommodating part 15. In the center of the display panel 45 of the moving display member 40 is located in the hole 51 and the display groove 11 of the body 10 formed so that the upper end of the length 31 of the control button 30 protrudes Check the movement to determine the damage of the frozen, refrigerated products and consists of a confirmation window 52 (see Figure 2).

3 and 4, the control button 30 has an upper end 31 inserted into the circular support 13 through the central opening of the lower portion of the body 10, as shown in FIGS. 34 is adjacent to the lower side of the engaging portion 14 and the groove 35 is fitted and supported by the engaging portion 14. Subsequently, the movement display member 40 has the guide part 43 positioned on the circular support plate 13 in the body 10, and the rotary shaft 41 is inserted into the length part 32 of the control button 30 and the housing part. The guide member 47 is inserted into 15 so that both side walls thereof are slidably fitted into the guide path 16 on both sides of the stopper 17. At this time, the holder of the control button 30 is located on the cutout 42. Of course, the control button 30 may be fixed by the position of the upper end 31 is inserted into the rotary shaft 41 after the movement display member 40 is fixed in the body (10). It is noted here that the control button 30 is supported so as not to rotate, so that the rotating shaft 41 of the movement display member 40 cannot also be rotated by the folder.

When the movement display member 40 is assembled to the body 10, the semi-solid material used in accordance with the principles of the present invention is filled in the space of the guide member 47 in the receiving portion 15. This semi-solid material may consist of PEG (POLYETHYLENE GLYCOL) 400 + PEG6000, lanolin, petrolatum or grease and has a certain roughness and malleability of the temperature sensor 20 as described below. It is opposed to the restoring force of the conversion unit 22 and overcomes this restoring force so that it is discharged to the outlet 46 to allow the movement of the guide member 40 and ultimately control the restoration of the temperature sensor 20.

To this end, as shown in FIG. 5, the temperature sensor 20 has an annular portion 21 fitted to the fixed rod 12 at one end thereof and extends from the length 23 to be bent around the rotating shaft 41. It is placed on the guide part 43 while being stacked, and the conversion part 22 is inserted in the support 44 at the other end. Therefore, when the temperature sensor 20 is assembled with the control button 30 and the moving display member 40 in the body 10, the display window 52 is matched with the display groove 11 so as to cover 50. Since the movable body 10 is sealed, the assembly of the temperature sensor control device is achieved with the upper end 31 of the control button 30 protruding over the hole 51.

Therefore, the temperature sensor control device, as shown in FIG. 5, the ring portion 21 of the temperature sensor 20 is fixed to the fixed rod 12, and the conversion unit 22 located on the guide portion 43 is a support ( 44, and the movement display member 40 is prevented from moving. That is, the movement display member 40 is maintained in the normal state before the upper end 31 of the control button 30 is pressed. At this time, the control button 30 is in a state in which the flange 33 thereof is coupled to the engaging portion 14 of the body 10 and at the same time the shaft thereof does not rotate the rotating shaft 41 of the moving display member 40 Even if the frozen or refrigerated food is attached at room temperature or above a critical temperature or exposed, the temperature sensor 20 is not reversely transformed into the second shape, and the movement of the display panel 45 is prevented from being rotated.

When the temperature sensor device is attached to the place of the refrigerated, frozen food, to be transported and stored, when pressing the control button 30 protruding over the cover 50 as shown in Figure 2 the shoulder hanging on the incision 42 The flange 33 with the drop falls into the cavity and at the same time the rotating shaft 41 is free and the movable display portion 40 is rotatable. Therefore, as shown in FIG. 6B, the temperature sensor 20 is in a state in which the conversion unit 22 is capable of restoring from the first shape to the second shape according to the external sensing temperature, and a restoring force is applied to the support 44. The moving display member 40 together with the display panel 45 is rotated as shown in FIG. 6A.

At this time, the semi-solid material is filled in the guide member 47 of the movement display member 40 located in the housing 15 of the fuselage 10, which is the conversion part 22 of the temperature sensor 20. Against resilience. Therefore, the restoring force of the conversion unit 22 can be adjusted according to the roughness and malleability of the semi-solid material, the size of the outlet 46 and the material of the temperature sensor 20.

Accordingly, the temperature sensor control device is operated to be installed on a frozen or refrigerated product such as a milk carton surface or a vaccine cap to be exposed to a temperature higher than the critical temperature or to room temperature so that a rapid deformation is delayed even when the temperature sensor 20 is transported. Ensure storage under normal conditions. If the frozen or refrigerated product is continuously exposed above the critical temperature, as illustrated in FIG. 6B, the conversion unit 22 is restored to a straight line having a second shape as shown in the straight line 22 to confirm the display panel 45. 52). This can confirm the damage of frozen and refrigerated products.

In this way, the present invention is to interlock the restoring force of the temperature sensor of the shape memory alloy with the semi-solid material to delay the restoration of the temperature sensor to secure the storage time at room temperature of the frozen and refrigerated products, and This makes it very convenient to check for damage.

In addition, the present invention can be applied to a variety of products by adjusting the illuminance and malleability of the semi-solid material in conjunction with the temperature sensor, the size of the outlet and the restoring force of the temperature sensor to prevent the incorrect disposal of normal refrigeration, refrigerated products.

Claims (5)

Display groove 11 formed at the upper part of the circumferential circumferential wall portion, the concentrically protruding concentric circle from the center thereof to form a cavity 14 ', and joining protruding in an arc shape on the center line inside the cavity 14'. A circular support 13 having a portion 14, an accommodating portion 15 which is integrated with the arc of the circular supporting portion 13 and is formed in a fan shape together with its wall portion, and is guided to both sides on one side of the accommodating portion 15. A fuselage 10 formed of a stopper 17 on which a furnace 16 is formed and fixing rods 12 protruding adjacent to a wall part by knitting on one side thereof on a center line thereof; Temperature sensor 20 having a ring portion 21, one end of which is coupled to the fixed rod 12, a straight portion 23 whose center is a straight line, and a conversion portion 22 of a first shape in which the other end is curved. ); A length portion 32 extending from the nurum portion 31 to a vertical length from the nurum portion 31, the lower end of the length portion 31 extends integrally from the circumference to the outside and is circularly supported. The groove portion 35 to be fitted with the engaging portion 14 of (13) is integrally extended therefrom directly below the flange portion 33 formed at the lower end thereof and the groove portion 35 of the flange 33 so that the circular support portion 13 A control button 30 configured to be in contact with the inner wall surface of the extension unit 34 which is adjacent to the lower side of the coupling unit 14; A rotary shaft 41 whose center is opened to accommodate the length 31 of the control button 30 and cutouts 42 are formed on both sides of its center line to accommodate the shoulder of the upper end of the flange 33, the rotary shaft ( 41 at the lower end of the guide portion 43, horizontally extending from the circumference of the circumference and positioned on the circular support portion 13 so that the length portion 23 of the temperature sensor 20 is positioned. It extends adjacent to the upper end of the wall portion of the body 10 in an arc shape, and downwardly integrally extends downward from the position corresponding to the arc circumference of the guide portion 43 to the lower side thereof, together with the outer wall portion of the rotating shaft 41 It is the same size and shape as the inside of the display panel 45 and the accommodating portion 15 of the fuselage 10, which forms the support 44 to which the conversion section 22 of the 20 is inserted and supported, and the upper and lower sides are opened. One side wall is formed with an outlet 46 through which semi-solid material is discharged, and the other side is opened. A movement display member 40 including wall members having guide members 47 movably fitted to guide paths 16 on both sides of the stopper 17 and integrally coupled with the display panel 45; and The temperature sensor 20, the control button 30 and the movement display member 40 therein are assembled therein and the control button 30 at the center thereof to seal the body 10 in which the semi-solid material is stored in the housing 15. ) Is located in the hole 51 formed to protrude the upper end of the length portion 31 and the display groove 11 of the fuselage 10, and confirms the movement of the display panel 45 of the moving display member 40 to freeze and refrigerate. Determination of damage to the product and the temperature sensor control device consisting of the lid 50 consisting of a confirmation window (52). The method of claim 1, A cutout 42 is formed in the rotation shaft 41 of the movement display member 40 to be coupled to the upper shoulder of the flange 33 of the control button 30 to prevent the operation of the temperature sensor 20. Pressing the control button 30, when the folder and the incision 42 is separated, the temperature sensor control device free to rotate the movement display member (40). The method of claim 1, The temperature sensor control device which allows the body 10 and the control button 30 to be molded at the same time because the coupling part 14 of the body 10 and the extension part 34 of the control button 30 are integrally formed as a placebo part. The method according to claim 1 or 2, The guide member 47 of the movement display member 40 is positioned in the accommodating portion 15, and both side walls of the guide member 47 are positioned on the guide path 16 to accommodate the semi-solid material to accommodate the temperature sensor 20. A temperature sensor control device that delays the return of the temperature sensor against the restoring force of the sensor. The method according to claim 1 or 3, A temperature sensor control device for controlling the operation of the temperature sensor so that the semi-solid material has a predetermined illuminance and malleability.