SE436954B - ADJUSTABLE THERMOSTAT - Google Patents

Description

45 šO 55 40 781346lv-0 [The beats are normally closed and opened by the actuator when a certain temperature is sensed. In the actuator, a bimetal is normally in the form of a diaphragm which is bent according to the temperature of the diaphragm, or a diaphragm which is subjected to a temperature-dependent pressure of a delimited liquid and bent accordingly.

Thermostats of the type specified are often used to regulate relatively strong currents and for this reason erosion of the contacts occurs through arc formation, and there is also a possibility that the contacts are welded together. Snap-operated diaphragms are therefore used to operate normally slow-acting switches, or slow-acting diaphragms are used to operate snap-operated switches, or snap-operated diaphragms are used to operate snap-operated switches.

Regardless of the design, the bending of the diaphragms is usually transmitted to the switch by means of an operating device in the form of a non-conductive, heat-insulating pin between the diaphragms and the contact rail of the switch. This pin is slidably mounted in the housing, usually in a bore that guides the pin. When the membranes are bent by increasing the sensed temperature, the pin moves the contact rail so that the contacts open. When the temperature is lowered, or when the thermostat is returned, the pin is returned to its initial position and the contacts close again.

This control pin and its support means are usually relatively close to the contacts of the switch, and when a strong current flows through the switch, a significant amount of heat is generated so that the pin and its support means are heated. In some cases, the heat generated can cause the pin to get stuck in its control so that the thermostat no longer works correctly.

Thermostats arranged for switching on and off (Cycling) according to sensed temperatures must intervene a very large number of times (for example several hundred thousand connections) without changing the set temperature levels at which the switch opens and closes. Membranes with a snap action in such thermostats always work with a temperature-dependent slow movement (so-called initial movement) before the snap movement past the dead center takes place. After a large number of duty cycles and / or a long time, the sensed temperature at which the initial movement occurs tends to change slightly, although the sensed temperature at which the membranes switch over may be substantially constant. 40 45 20 25 BO 55 40 7813464-0 \. \. L Resettable thermostats, which are used to protect equipment from working at too high a temperature, normally break an electrical circuit to the equipment when too high a temperature is detected and shut off. not the circuit before the thermostat is reset. The design of such thermostats can be substantially similar to the design of thermostats for connection and disconnection, except that the diaphragm affecting the diaphragm in resettable thermostats usually does not bend significantly when lowering the sensed temperature after the switch contacts have been opened. Reset mechanisms have been inserted in these thermostats to reconnect the contacts and return the diaphragms. Such a reset mechanism usually includes a manually depressable reset button.

Excessive temperatures usually occur in appliances when performing certain maintenance work. For example, when the fiber trap in a fabric dryer is filled so that the air flow through the dryer is obstructed, the air temperature in the dryer becomes too high with the result that the thermostat stops the further work of the dryer. Normally, the fiber trap must then be cleaned and the thermostat reset to restart the dryer.

In some previously known thermostats it was possible to close the contacts of the thermostat switch again by pressing a reset button when it was still sensing the high temperature. It was then possible for a worker who did not know the equipment, or who did not pay attention to any damage to the equipment, to lock the return button in the depressed position so that the thermostat did not work at all and kept the contacts constantly closed.

To prevent damage to the equipment as a result of malfunction, previous reset mechanisms were used that could not close the thermostat switch contacts before the sensed temperature had dropped below the specified level. This type of resettable thermostat is known as "trip safe".

Known trip-safe thermostats were equipped with a feedback mechanism which entailed increased costs and tended to reduce the reliability of the thermostats. Other mechanisms have been designed in such a way that the contact rail of the thermostat could be resiliently bent by influencing forces when an attempt was made to return the thermostat too early and too much force was applied to the feedback mechanism.

The present invention provides an improved trip-safe reset mechanism of simple and reliable design that prevents mechanical damage to the thermostat switch when attempts are made to reset the thermostat prematurely.

The invention relates to a resettable thermostat comprising a housing, a thermally reacting actuator with a surface which is moved relative to the housing to a certain position upon sensing a certain temperature level and remains in this position regardless of whether the sensed temperature drops until the surface is restored. a switch having a first fixed contact and a second movable contact attached to a first hand by an elastic rail which is attached at its opposite second end to the housing and normally presses the second contact against the first contact, an actuator for the switch between the the thermally responsive actuator and the rail for transmitting movements from the surface of the actuator to the rail to open the contacts as the surface is moved to the determined position, which actuator has a portion for engaging the rail at a first point between the ends of the rail, and a reset reset mechanism of the contacts and resetting of the thermal actuator to e tt position at a distance from the determined position.

This thermostat according to the invention is characterized in that the reset mechanism comprises a reset means mounted for limited movement in a reset direction relative to the rail and an elastically flexible power transmission means between the reset means and the rail for applying a limited reset force against the rail to push it in the direction closing the contacts when the sensed temperature is below the determined temperature level, which elastically flexible power transmission means is arranged to engage the rail at a second point between said first point and the second attachment end of the rail to push the first end of the rail in the direction from the first fixed the contact when the reset means applies the reset force at a sensed temperature above the determined temperature level.

If the sensed temperature is such that the thermostat would not be returned, the reset force applied to the rail is insufficient to reset the thermostat or momentarily close the switch contacts and is also insufficient to damage the contact rail by bending.

In a preferred embodiment of the thermostat, the elastically flexible power transmission means consists of a leaf spring arranged to engage against the rail at the second point, which spring has one end attached to the housing, a resiliently flexible portion between it in the housing 10? s1z4è4ïo attach the end and the other point of engagement and an end portion projecting from this point of engagement for engagement with the restoring means.

In a further preferred embodiment, the restoring means is arranged to be moved in the direction of the rail during the restoring movement, wherein means for limiting the restoring movement are taken. These devices comprise a stop on the restoring means and a stop on the housing, which stops engage against each other to limit the movement of the restoring means in the direction of the rail with the restoring means at a distance from the rail.

When the sensed temperature becomes too high, the thermally reacting actuator causes the contacts to open. When the sensed temperature then drops below the too high level, the reset means is moved in the direction of the rail to reset the thermostat. In this case, sufficient force is transmitted to the thermally reacting actuator via the contact rail to allow transmission of the means so that the contacts are closed again.

If attempts are made to reset the thermostat prematurely, i.e. if too high a temperature is still detected when the reset mechanism is actuated, the limited movement of the reset means limits the force applied to the rail via the elastically flexible power transmission means so that the contacts cannot be closed against the action of the thermal actuator.

Due to the action of the elastically flexible power transmission means and the limited movement of the resetting means, the contact rail is not subjected to harmful bending which could break the rail during reset or attempts to reset the thermostat. The invention is described below in the form of exemplary embodiments and with reference to the accompanying drawings.

Fig. 4 is a side view of a thermostat according to the invention.

Fig. 2 is a cross-sectional view taken along line 2-2 of Fig. 4. Fig. 5 is a sectional view taken along line 5-5 of Fig. 2. Fig. 4 is a sectional view taken along line 4-4 of Fig. 5. Fig. 5 is a sectional view taken along line 5-5 of Fig. 4. Figs. 6-8 are schematic sections similar to Fig. 5, showing parts of the thermostat in different working classes.

Fig. 4 shows a thermostat 40 according to the invention for protecting an electrically controlled apparatus against damage by overheating.

The thermostat 40 is mounted on a panel 42 by means of screws 44 and connected to electrical supply lines 46, 48 for the apparatus.

The thermostat 40 is arranged to cut off the power supply to the apparatus at a certain sensed temperature level in the apparatus. To restore power to the appliance, the thermostat 40 must be reset manually.

In the preferred embodiment of the invention, the thermostat 40 comprises a housing 20, a thermally responsive actuator 22 connected to the housing 20, switch 24 (schematically shown in Fig. 4) in the housing 20, and a control device for the switch in the housing. The actuator 25 transmits actuating motion between the actuator 22 and the switch 24 to open and close the switch. As shown in Figs. 2-5, the housing 20 comprises a housing part 26, connections 28, 50 attached to the part 26 and insulating end caps 52,54 located at opposite ends of the housing part. The part 26 is suitably made of rigid molded plastic, such as bakelite, and has a central transverse wall 56 and generally cylindrical outer wall portions 58,40 (Fig. 5) extending axially from the central wall 56 towards opposite ends of the housing part.

Poon suuAuTy 40 45 25 50 40 7813464-0 7 The wall 58 extends concentrically about the longitudinal axis of the housing and terminates at an annular end surface 42. Opposite reinforcing wall portions 58a, 58b (see Fig. 2) extend radially inwardly from the wall itself and form surfaces 44 in the same plane slightly below the end surface 42 for supporting the lid 52. The wall 58 and the wall 56 form a space 46 in which the switch 24 and its operating device 25 are arranged.

The projecting end of the wall 58 is provided with support means for the thermal actuator in the form of projecting lugs 50 distributed along the side 42 and undercut portions 52 (Fig. 5) on the outside of the wall 58, which form flange portions 54 for connecting the actuator 22.

The opposite end of the housing part 26 forms a low space 56 bounded by the wall 40 and the wall 56 (see Fig. 5). Distributed reinforcement ridges 60 extend along the wall 40 and terminate immediately below the end of the wall to form support surfaces 62 against which the cover 54 abuts. Iocket 54 is attached to the housing with suitable screws.

The connections 28, 50 are attached to the wall 56 and support the switch 24 in the space 46. The connections are diametrically distributed in the housing and each connection consists of a U-shaped electrically conductive metal plate which is attached to the wall 56.

The connection 28 has an intermediate portion 66 and legs 67 extending from the intermediate portion through connecting grooves 68 in the wall 56 to the space 56. A leg forms a connection 70 extending from the housing through a groove in the cover 54 for connection to the conduit 18. The other the leg ends in the space 56. The intermediate part of the connection 28 is supported by ridges 72 in the housing (see Fig. 4) and the legs 67 support against the wall 56 in the space 56 so that the connection 28 is thereby firmly fixed in the housing.

The connection 50 is of a similar design to the connection 28 and comprises an intermediate portion 74 in the space 46 and legs 75 extending through correspondingly shaped grooves 76 to the space 56. A leg 75 forms a connection 78 projecting from the housing through the cover 54 for connection to the conduit. 16 while the other leg ends in the space 56. Each leg 75 has tabs 75a in the space 46 which abut against the wall 56. Each leg 75 abuts the opposite side of the wall 56 in the space 56 so that the connection 50 is firmly fixed in the housing.

The switch 24 comprises a contact 80 (Fig. 5) which is attached to and electrically connected to the intermediate portion 74 of the connection 50 and facing the wall 56; a movable contact 82 disposed between the contact 80 and the wall 56; and a resiliently flexible contact rail 84 which supports the movable contact 82. The rail 84 is suitably formed of a rectangular thin leaf spring of beryllium copper with opposite sides 84a, 84b. An end portion 85 is connected to the connection 28 by rivets 86 (see Fig. 4) so that the rail extends cantilevered through the space 46. The contact 82 is supported in the projecting free end 87 on the leaf spring side 84a and is movable to and from the contact 80 by bending the rail. The rail 84 is suitably biased to normally press the contacts 80,82 into abutment with each other so that the switch 24 is normally closed. In the preferred embodiment of the invention, a pair of parallel stiffeners are provided on the rail 84 to limit the bending of the rail to the end portion 85.

When the contacts 80,82 engage with each other, a circuit is closed from the connection 78 through the connection 50, the contacts 80,82, the rail 84 and the connection 28 to the end connection 70. The circuit is broken when the rail 84 is bent to separate the contacts 80,82 .

The thermally responsive actuator 22 acts on the switch 24 according to sensed temperatures via the actuator 25. The actuator 22 can be of any suitable or conventional type and is in the case shown hydraulically actuated.

The actuator 22 forms a hermetically closed chamber 88 (see Fig. 5) formed by a pressed metal housing 90, a flexible membrane 92 attached to the housing 90, and a capillary tube 94 connected to the housing 90 and extending to one or more several places in the appliance where the temperature is to be sensed. The chamber 88 is filled with an evaporable liquid which evaporates in each place where a predetermined relatively high temperature prevails. The pressure in the chamber 88 varies according to the vapor pressure of the liquid at the highest temperature prevailing along the capillary tube or the wall of the housing 90.

The housing 90 is suitably cup-shaped and has a generally conical bottom wall 98 with a central opening 99 in the tip communicating with the tube 94, a projecting cylindrical side wall 100 extending from the bottom wall 98 concentrically around the wall 58 of the housing and a radially extending flange 102 formed to mounting tabs 404 on opposite sides of the thermostat (see Fig. 1).

The diaphragm 92 preferably consists of a thin circular disc 10 15 25 §O \, \ | Of resilient material welded to the housing 90 along its circumference and concentric with the side wall 100. The thermostat housing is enclosed within the side wall 100 with the lugs 50 firmly abutting the diaphragms 92 along its circumference. The side wall 100 is firmly attached to the thermostat housing by extensions on the side wall 100 which engage the release 52 of the thermostat housing so that the actuator 22 is securely clamped to the housing via the flange portions 54.

When the actuator 22 and the thermostat housing 20 are mounted, the diaphragms 92 are centered about the longitudinal axis of the housing and are accurately axially positioned relative to the contact rail 84.

The diaphragm 92 has a slightly depressed central portion 92a which during snap movement can be moved between stable positions on opposite sides of a plane extending through the circumference of the diaphragm. The central portion 92a is surrounded by an annular resilient portion 92b of truncated conical shape which enables said snap movement. The resilient portion 92b acts to some extent in a similar manner to a conical washer spring. As the sensed temperature is increased towards a certain level, the pressure in the chamber 88 increases correspondingly and the resilient portion 92b tends to flatten towards the plane through the circumference of the diaphragm. This successive movement, which precedes the snap movement of the central portion 92a, is called the initial movement.

When the sensed temperature reaches a level that is too high for the apparatus, the diaphragms 92 perform a snap movement through the plane through its circumference to a stable position in which the central portion 92a projects against the contact rail 84.

In the thermostat shown in Figs. 1-8, the resilient portion 92b is designed so that the diaphragms are pressed relatively strongly against their projecting position over the dead center. Thus, when the pressure in the chamber 88 is reduced due to the sensed temperature falling, the diaphragms do not return to their initial position since the forces applied to the diaphragms are not sufficient to overcome the counterforce from the resilient portion 92b. To return the diaphragms to their initial position, a manual return force must be applied to the central portion 92a. This return force or reset force is applied to the diaphragms 92 and the switch 24 via the actuator 25.

In the embodiment of Figs. 1-8, the actuator 25 comprises an actuating mechanism 110 arranged to transmit the movement of the diaphragms 92 to the contact rail 84 to open the contacts and a trip-safe reset mechanism 112 for closing the cone again. the beats 80,82 and return the diaphragms 92 via the rail 84 and the mechanism 110.

The mechanism 110 is designed and arranged so that the heat generation by electric current over the closed contacts does not have an adverse effect on the work of the mechanism. Furthermore, the possibility is reduced that the erosion that normally occurs on the contacts does not result in any significant change in the thermostat's setting after a large number of work cycles. The mechanism 110 comprises a lever 114 arranged in the space 46 between the actuator 22 and the cover 52 and the switch 24. The arm 114 is pivotable about a bearing 116 for transmitting movement between the switch 24 and the diaphragms 92. The arm 114 is suitably made of rigid heat-insulating molded plastic and extends from a point at the periphery of the housing at a distance from the switch contacts radially inwardly toward the longitudinal axis of the housing.

The arm 114 has opposite projecting cam-shaped portions 120, 122, which engage the membranes 92 and the contact rail 84, respectively. The portion 120 of the arm is located opposite the central portion of the membranes 92 and projects through a central opening 52a in the cover 52 for engagement with the membranes. The portion 122 of the arm is located further away from the bearing 116 in the end portion of the arm and abuts against the contact rail 84 between its end portions 85,87 so that relatively little movement of the projecting end portion of the arm 114 results in a substantial opening or closing movement of the contacts 80. , 82. The bearing 116 is spaced from the contacts 80,82 so that heat transfer to the bearing from the contacts is reduced to a minimum and the possibility that the bearing 116 would heat up and prevent the movement of the arm 114 by cutting is eliminated. the bearing 116 is formed by pins 150,152 (Fig. 2) made in one piece with and on opposite sides projecting from the arm 114, which pins are received in correspondingly shaped seats 154,156 in the housing 26. As shown in Fig. 4, each pin 150,152 has a semi-cylindrical bearing surface 140 which merges into a concentric end portion 142 of truncated conical shape. The seats 154,156 likewise have a semi-cylindrical bearing surface 144 and a bearing surface 146 of truncated conical shape which by play adjoins the bearing surfaces of the associated pin. The conical bearing surfaces of the pins and seats aim to keep the arm centered between the seats, while the semi-cylindrical bearing surfaces allow the arm to pivot about the axis of the bearing 448.

The yoke 32 on the thermostat housing extends between the diaphragms 92 and the arm 444 immediately adjacent the pins 450,452 to ensure that the bearing 446 is properly held together during use of the thermostat. Due to the offset placement of the cam portions 420,422 on the arm, compressive forces from the diaphragms 92 against the arm and rail 84 provide a pair of forces acting in the bearing 446 and helping to hold the bearing together.

When the arm 444 is pivoted about the bearing shaft 448 during operation of the contacts, the cam portion 422 engages against the rail 84 and performs a sliding movement along the rail. This sliding motion provides a slight abrasion, or abrasion, which reduces the height of the portion 422. When the contact 82 and the portion 422 lie on the same side 84a of the rail 84, the wear of the portion 422 will compensate for the normally occurring erosion of the contacts 80,82 during normal opening and closing.

The trip-safe mechanism 442 includes a manually actuated reset pin or button 460 supported in the housing 20 for movement along the longitudinal centerline of the housing to and from the side rail 84b of the contact rail, and a resiliently flexible spring 462 cooperating between the reset pin and the rail 84. As shown in Figs. 5 and 6. The pin 460 has a portion 464 projecting through a corresponding opening 466 in the lid 54, a collar 468, and an end portion 470 extending from the collar 468 through the wall 56 into the space 46. The wall 56 has a central opening 472 with a shoulder for receiving the collar 468 and the end portion 470. the opening 466 in the lid 54 has a smaller diameter than the collar 468, so that the pin 460 is retained in the housing through the lid 54.

The portion 464 of the pin can be manually pressed so that the pin 460 is inserted into the housing towards the side 84b of the rail 84 but the movement of the pin in the housing is limited so that it cannot engage against the rail 84. The length of the end portion 470 of the pin is so selected that the collar 468, when the pin is pushed into the housing, engages the shoulder 472a in the opening 472 and prevents further movement of the pin, thereby limiting the force that can be applied by the pin to the spring 462.

The spring 462 is suitably a leaf spring which is connected at one end to the connection 28 by rivets 86 and which extends cantilevered from the connection 28 along the side 84b of the rail. The spring 40 is preferably provided with a recess which forms a stop 480 at a distance from the projecting end 482 of the spring.

The stop 480 abuts with a light pressure against the side 84b at a point 484 between the end portion 85 of the rail and the point of engagement between the rail 84 and the cam portion 422 of the arm 444.

The projecting end 482 of the spring extends over the end portion 470 of the pin so that the pin, when the contacts 80,82 are open, can be depressed as far as possible and engage against and resiliently; bend the end 182 of the spring.

If the highest sensed temperature in the apparatus is below the set limit for excessive temperature, manual full depression of the reset pin 460 will resiliently bend the spring 462 sufficiently for the spring to abut against the rail 84 with sufficient force to return the diaphragms. The restoring force is transmitted through the rail 84, the portions 422, 420 of the arm and to the diaphragms 92 and overcomes the force developed by the resilient portion 92b of the diaphragms so that the portion 92a of the diaphragms springs back through the plane through the diaphragm circumference in the direction of the switch 24.

Figs. 6 and 7 schematically show the design of the reset mechanism and its position relative to the diaphragms 92, the arm and the switch 24 when the contacts of the switch are closed and open, respectively. Fig. 8 shows the reset mechanism with associated components when an attempt is made to reset the thermostat while a too high sensed temperature prevails in the apparatus.

As shown in Fig. 8, the portion 92a of the diaphragms has performed a snap motion over the dead center and is pressed against the switch 24 by the spring action of the resilient portion 92b of the diaphragms and the liquid pressure in the chamber 88. The contact bars 80,82 are thus kept open. The reset pin 460 is manually depressed into the thermostat housing to the extent possible, resulting in the spring 462 resiliently bending to abut against the rail 82 with limited restoring force. The restoring force against the rail 84 is applied at a distance from the point of contact between the rail 84 and the portion 422 of the arm, which results in the rail 84 resiliently bending slightly so that the distance between the contacts 80,82 is further increased. The limited restoring force transmitted via the spring 462 is insufficient to overcome the internal fluid pressure against the diaphragm 92, so the diaphragms are not restored. Furthermore, the limited restoring force is insufficient to permanently deform the rail 81+. It is observed that the end portion 170 of the reset pin is at a sufficient distance from the rail 81+ so that the rail does not come into abutment against the end portion 482 of the spring when the reset pin is depressed as far as possible. The restoring force against the rail 84 is thus limited according to the force developed by the spring 162.

Claims (3)

va134e4-o ,, Patent claim A resettable thermostat comprising a housing (20); a thermally responsive actuator (22) having a surface (92a) that is moved relative to the housing to a certain position upon sensing a certain temperature level and remains in that position regardless of whether the sensed temperature drops until the surface is restored; "a switch having a first fixed contact (80) and a second movable contact (82) attached to a first end of an elastic rail (84) which at its opposite second end is attached to the housing and normally presses the second contact against the first an actuator (110) for the switch between the thermally responsive actuator (22) and the rail (84) for transmitting movements from the surface of the actuator (22) to the rail to open the contacts as the surface is moved to the determined position, which actuator (110 ) has a portion (122) for engaging the rail (84) at a first point between the ends of the rail; and a reset mechanism (112) for reconnecting the contacts and resetting the thermal actuator (22) to a position remote from the determined position. , characterized in that the reset mechanism (112) comprises a reset means (160) mounted for limited movement in a reset direction relative to the rail (84) and an elastically flexible k power transfer means (162) between the reset means (160) and the rail for applying a limited reset force against the rail to push it towards closing the contacts (80, 82) when the sensed temperature is below the determined temperature level, which elastically flexible power transfer means ( 162) is arranged to engage the rail at a second point (184) between said first point and the second mounting end (85) of the rail (84) to push the first end of the rail in the direction of the first fixed contact (80) when the resetting means (160) applies the reset force at a sensed temperature above the determined temperature level. 70134640-0 fr Thermostat according to claim 1, characterized by the elastically flexible power transmission means (162) consisting of a leaf spring arranged to engage against the rail (84) at the second point (184), which spring has one end attached to the housing (20), a resiliently flexible portion between the end attached to the housing and the second engagement point (184) and an end portion projecting from this engagement point for engagement with the restoring member (160). Thermostat according to claim 1, characterized in that the reset means (160) is moved in the direction of the rail (84) during the reset movement, wherein means for limiting the movement of the reset means comprise a stop (168) on the reset means and a stop (172a) on the housing (20), which abutments engage against each other to limit the movement of the restoring means in the direction of the rail (84) with the restoring means at a distance from the rail.