DE69934338T2 - Improvement for a thermal control of an electric heating element - Google Patents

Description

AREA OF INVENTION

These The invention relates to improvements in temperature controls for electrical heating elements, and, in particular, but not exclusively, relates to the arrangements which in our British Patent Application No. 9717144.1 on August 12, 1997, and 9724382.8, filed on November 18, 1997, are disclosed.

GENERAL STATE OF THE ART

In our above mentioned British Patent Application No. 9717144.1 are very different Substructures or support elements described for attachment to a flat heating element, especially a Dickschichtheizelement, are suitable and on arrangements for assembly from several heat sensors at selectable variable Bodies with it. The described embodiments include a device inlet connector, the one on the how present manufactured Otter Controls CP7 inlet connector, which is an inlet connector for a cordless device, which allows that application in any rotational orientation of the two is deposited on its base, with several legs all in the same plane in different directions from the connector outwards extend, and every thigh over Arrangements for mounting one or more thermal sensors at a number of different locations on the leg. The invention British Patent Application No. 9717144.1 discloses the provision in terms of flexibility the arrangement of sensors on flat heating elements, among others to adapt to the different needs of different equipment manufacturers as their basic principle.

In British Patent Application No. 9717144.1 is proposed simple contact stat heat sensors as the sensors to be attached to the legs, and an exemplary contact static heat sensor, the for This purpose is well suited in our British patent application No. 9724382.8. As described therein, the contact stat thermal sensor includes a domed one Disc bimetal that deals with a snap action between oppositely arched configurations moves when the sensed Temperature over rises to a predetermined degree, wherein the bimetal movement through transmit a push rod to a pair of switch contacts becomes.

Of the in our British Patent Application No. 9724382.8 Contactstat thermal sensor represents only a primary Degree of thermal protection, because he is no facility for providing a secondary or supportive Degree of protection, which, in the case of a, albeit improbable, Failure of the main protection, for example due to a failure of the Bimetallic or a welding together of the switching contacts, effective shall be.

The document EP-A-0 014 102 discloses a thermostat for insertion into a power supply line by means of terminals. Inside the thermostat, a switch, which has contacts and a flexible element capable of bending around a fulcrum, is operated according to the ambient temperature by means of a bimetal disc acting through a push rod. In normal operation, the features become 24 and 26 (please refer 2 ) is held in contact with each other by another push rod carried on a fusible block, which in turn is supported on a metal plate. However, if the thermostat is overheated, the block melts, which removes the post from the push rod, and this allows a spring to push the elastic member downwardly so that it does 24 . 26 from the inner end of the connection 15 separates.

TASKS AND BRIEF SUMMARY OF THE INVENTION

Accordingly, it is the main object of the present invention is a contact stat heat sensor to be provided with those in our British patent application No. 9717144.1 can be used and a primary and a secondary one Provides a degree of protection.

According to the present invention there is provided a contact heat sensor comprising a spring-loaded electrical conductor which serves at opposite ends thereof as the movable contacts of a first and a second set of switch contacts which, in use, are held closed against the bias of the spring-loaded electrical conductor. wherein the first set of switch contacts is arranged to be held closed by a bimetallic switch actuator configured to allow the first contacts to open at a predetermined temperature and the second set of switch contacts to be arranged in that it is held closed by an element of fusible material adapted to allow the second contacts to open at a temperature above the operating temperature of the bimetallic switching actuator, the anord tion is such that when using the Sen In the event of failure of the bimetallic switching actuator upon opening of the first set of switch contacts, the second set of switch contacts may be opened in response to melting of the fusible material element.

To an embodiment of the present invention as detailed below is described, the primary Switch contacts from a fixed contact and a movable contact at one end of a spring metal beam, and the other end of the beam is in electrical contact with an electrical Connection part of the Kontaktstats held by means of a fusible thermoplastic molded plastic rod, wherein the bar over a support is claimed when the primary switch contacts on the one End of the beam are closed and the other end is the electric Connecting part touched. When the bimetallic actuator works, allows the push rod, that one end of the beam from the firm contact the device recoils and if that does not happen and the contacts on one end the bar will remain closed, the increasing temperature cause the thermoplastic plastic rod to soften, which allows is that the other end of the beam from the electrical connection part snaps back.

The The above and other features of the present invention will become apparent considering the following detailed description that with reference to the accompanying drawings, best understood.

DESCRIPTION THE DRAWINGS

1 FIG. 10 is an exploded perspective view of a contact post embodying the present invention, and FIG

2 FIG. 12 is a cross-sectional view of the contact state of FIG 1 ,

DETAILED DESCRIPTION OF THE EMBODIMENT

With reference to 1 For example, the contact-static thermal sensor shown in FIG. 1 comprises a self-recovering domed disc bimetal 1 , a push rod 2 and a pair of switch contacts 3 and 4 , where the contact 3 forms the movable contact of the switch contacts and at one end of a Federmetallbalkens 5 is attached and the contact 4 forms the fixed contact of the switch and on a Pressmetallanschlussteil 6 the device is attached.

A body part 7 the Kontaktstats is formed of a temperature-resistant plastic or ceramic material and has a bore 8th on which to accommodate the push rod 2 serves. The disc bimetal 1 is at the top of the body part 7 in a pressed metal cap formed of, for example, copper or aluminum 9 housed, which is adapted to the upper end of the body part 7 to be pressed. As in 2 shown, the bimetal sits 1 under the cap 9 with its edge on one side of the bimetallic disc on the upper end of the push rod 2 resting and on the diametrically opposite side of the disc on a small ledge 10 rests. A middle depression 11 in the middle of the cap 9 provides a support with the bimetal disc 11 ready and can be regulated by deformation of the cap to regulate the bimetallic operation.

A second part of the body 12 The Kontaktstats is suitable, with the first-mentioned body part 7 to be joined together to the beam 5 , the connection part 6 and another connection part 13 to catch between the two body parts. The two connecting parts 6 and 13 have sections 14 respectively. 15 on, which is when the two body parts 7 and 12 are joined, extend from the Kontaktstatkörper to produce a spring contact with contact points, which are provided on a Dickschichtheizelement whose temperature is to be controlled by the Kontaktstat.

The cap 9 has a radial extension 16 designed to be the top of a pole 17 of fusible material, for example a thermoplastic material, and in the body part 7 is an opening 18 trained to the lower end of the rod 17 into the inner chamber, which is defined when the body parts 7 and 12 are joined together. How best in 2 As can be seen, the lower end of the rod hits 17 on the end of the spring metal bar 5 opposite to that end, which is the movable switching contact 3 carries, with the bar 5 at the end in question 19 bent upward to ensure a secure arrangement of the rod 17 with the relevant bar end 19 Ensure and ensure that only forces in the axial direction on the rod 17 be exercised.

Positioning approaches are at the longitudinal edges of the beam 20 provided with training 21 which in the body parts 7 and 12 are cooperate to properly arrange the beam when the contact is assembled. An upright element 22 on the body part 12 is provided at a convenient time (as described below) at a location that is closer to the end 19 as on the other end, which is the moving contact 3 of the switch, located, an upward push on the bar 5 to apply.

As in 2 Showing the contact act in its normal cold state, the assembly of the contact post causes the beam 5 which, in its unloaded condition, as in 1 Shown is flat, between its end carrying the movable contact, to which it is due by the action of the bimetal 1 and the push rod 2 is held down in a contact closure state, and its other end 19 where he goes through the pole 17 made of fusible material, with the upper end resting on the cap 9 meets, is held down and over and in electrical contact with an upright training 23 on Pressmetallanschlussteil 9 extends, is bent upwards. In this state of the Kontaktstats can current between the two connection parts 14 and 15 flow.

In such an over-temperature condition that causes the bimetal disc 1 snaps into their oppositely curved configuration, the movement of the bimetal would be the moving contact 3 normally allow, from firm contact 4 to jump away without the one between the other end 19 of the beam 5 and training 23 at the connection part 13 interrupt contact made. If this does not happen, because for example the bimetal 1 rips or the switch contacts 3 . 4 Welding, power will continue to flow through the contact to an associated heating element and the heating element temperature will continue to rise. At some point, the fusible rod becomes 17 soften or melt and become the end 19 of the beam 5 from the electrical contact with the training 23 at the connection part 13 is ready to snap back. The fusible rod 17 thus provides a secondary or supportive degree of protection that acts when passing through the bimetal 1 provided main protection fails.

At the lower part of the body 12 is an education 24 to allow the contact assembly to be assembled with a carrier as described in our above-mentioned British Patent Application No. 9 717 144.1.

The upright element 22 can in like in 2 shown cold state of Kontaktstats with the beam 5 but not necessarily, because this is the condition of the fusible rod 17 to the end 19 of the beam 5 and the impact of the beam 5 on the from the connection part 13 high level education 23 will serve to load the beam sufficiently to ensure proper operation of the primary contacts 3 . 4 sure. But if the pole 17 softens or melts in the secondary protection mode of the contact post and the beam begins to snap back to its normal flat state and thereby the electrical contact between the end 19 of the beam and the training 23 interrupts only the contact of the beam with the upright element 22 cause a sustained force to cause the beam to continue to snap back and provide a safe electrical gap between the beam 5 and the connector 13 opens. If the upright element 22 in the cold state of the Kontaktstats not with the bar 5 Being in contact, the forces are between the end 19 of the beam and the training 23 at the connection part 13 be optimized, so that a silvering of these parts for a better electrical contact may not be necessary.

The geometry of the arrangement described and illustrated is of such a nature that when the contact state is cold, a high force is applied to the fusible bar 17 is exercised and a lower force on the push rod 2 is exercised, reflecting the lower actuation force available from the bimetallic disc. The advantage of this arrangement is that of a short, stiff spring, namely the part of the beam 5 between the training 23 and the beam end 19 A very high force is available to deform the fusible rod at the appropriate temperature 17 to start. Once the deformation has started, the upright element stops 22 a lower force from a longer, more resilient spring, namely the part of the beam 5 between the training 22 and the beam end 19 , ready to provide sufficient deformation of the rod 17 provide a safe distance between the beam 5 and training 23 at the connection part 13 to open.

While the invention has been described above with reference to a particular embodiment, it will be understood that those skilled in the art will come to various modifications and variations without departing from the scope of the invention as set forth in the following claims. Although, for example, the fusible rod 17 is preferably formed of an electrically insulating thermoplastic material, since it is connected to the current-carrying beam 5 In contact, it could be formed of a suitable eutectic metal alloy material with an electrically insulating cap. In addition, the rod could 17 made of fusible material so that the upper end of the rod 17 when using the Kontaktstats directly on the heating element, rather than in the cap extension 16 to be caught. In this arrangement, the beam would 5 in the free-standing state of the Kontaktstats, namely, before it was attached to a heating element, are not charged, and he would only be charged after the Kontaktstat with the Hei zelement was assembled, this structure causes the rod 17 is driven in the axial direction to the interior of the Kontaktstats to the end 19 of the beam 5 about the upright element 23 at the connection part 13 to bend.

The embodiment includes also a contact heat sensor a, which is a bimetallic actuator in the form of a domed disc bimetal that is opposed by a snap action between domed Configurations is movable, with the bimetallic actuator is set up in the normal operation of the sensor a set to operate from switch contacts, and wherein an element comprising a fusible material thereto is set up to interrupt an electrical path through the sensor, if the main protection, by the bimetal and the switch contacts is failed in operation and the fusible material of a temperature above the normal operating temperature of the bimetal is exposed thereby characterized in that the set of switch contacts is set up is actuated by a push rod becoming responsive to movement of the circumference of the bimetal if this snaps between its opposite arched configurations, wherein the push rod cooperates with one end of an elongate spring element, that over extends at least one support, which serves to the spring element to load, and at the other end to the element, the one includes fusible material, cooperates to the state of electrical path to determine.

Preferably the sensor comprises a sensor body, the one with a heat-conducting Metal cap is provided, and the bimetal is between the cap and the sensor body trapped, with the cap shaped to be a support defined defining the position of the center of the bimetal.

Preferably the cap is deformable to adjust the position of the support.

Preferably the element of fusible material comprises a push rod, the one with the other end of the oblong Federelement cooperates to determine whether an electrical Contact between the oblong Spring element and a conductor of the sensor is made or not.

Preferably works the push rod of fusible material to the spring element over a bend upstanding part of the head.

Preferably is the high part of the conductor at the other end of the spring element closer than the one end of the same.

Preferably is in a body part provided an upright element of the sensor, wherein the upright element as a support for an interaction with the spring element when breaking the electrical Path serves.

Preferably is the element of fusible material outside the circumference of the bimetal arranged.

It will be appreciated that the embodiment provides a contact heat sensor that includes a bimetallic actuator 1 . 2 which is adapted to operate a set of switch contacts during normal operation of the sensor, and wherein an element 17 comprising a fusible material adapted to interrupt an electrical path through the sensor if the main protection provided by the bimetal 1 and the switch contacts is provided, fails in operation and the fusible material is exposed to a temperature above the normal operating temperature of the bimetal.

The bimetallic actuator preferably comprises a domed disc bimetal 1 which is movable with a snap action between oppositely curved configurations.

Preferably, the set of switch contacts is adapted to be by a push rod 2 to be actuated, based on a movement of the circumference of the bimetal 1 appeals when this grabs between its opposing domed configurations.

Preferably, the sensor comprises a sensor body 7 , with a heat-conductive metal cap 9 is provided, and the bimetal 1 is trapped between the cap and the sensor body, the cap being shaped to be a support 11 defined defining the position of the center of the bimetal.

Preferably, the cap 9 deformable to the position of the support 11 adjust.

Preferably, the element comprises 17 comprising fusible material, a push rod which serves to make electrical contact between a spring element 5 and a leader 13 of the sensor.

Preferably, the push rod works 17 made of fusible material, around the spring element 5 over an upstanding part 23 of the leader 13 to bend.

Preferably, the spring element 5 elongated and serves at one end thereof as the movable contact of the set of switch contacts, the bimetal 1 are assigned, and serves at the opposite end thereof in cooperation with the rod 17 made of meltable material.

Preferably, the upstanding part 23 of the leader 13 the opposite end of the spring element 5 closer than one end of it.

Preferably, in a body part of the sensor, an upright element 22 provided, wherein the upright as a support for an interaction with the spring element 5 when interrupting the electrical path is used.

The embodiment also provides a contact heat sensor comprising a spring-loaded electrical conductor 5 acting on opposite ends thereof as the movable contacts of a first and a second set of switch contacts, which are normally held against the Vorspan voltage of the sprung electrical conductor in the closed state, wherein the first set of switching contacts is arranged so that it by a bimetallic switching actuator 1 . 2 is held in a closed state, which is adapted to allow the first contacts to open at a predetermined temperature, and the second set of switch contacts is arranged to pass through an element 17 is kept in a closed state of meltable material adapted to allow the second contacts to open at a temperature above the operating temperature of the bimetallic switching actuator, the arrangement being such that when the sensor is used in the event of failure of the bimetallic switching actuator upon opening of the first set of switch contacts, the second set of switch contacts may be opened in response to melting of the fusible material element.

Preferably, the electrical conductor is formed of spring metal and is in the cold state of the sensor in which both sets of contacts are closed, by the action of the bimetallic switching actuator 1 . 2 at one end and the effect of the element 17 of fusible material at an opposite end via a support 23 bending, wherein bending the spring metal conductor provides the necessary spring force to actuate the two sets of switch contacts.

Claims (20)

Contact heat sensor comprising a spring-loaded electrical conductor ( 5 ), which at opposite ends thereof serve as the movable contacts of a first and a second set of switch contacts which are held in use against the bias of the spring loaded electrical conductor in the closed state, the first set of switch contacts being arranged to pass through a bimetallic shift operating element ( 1 . 2 ) is maintained in a closed state, which is adapted to allow the first contacts to open at a predetermined temperature, and the second set of switch contacts is arranged to pass through an element (10). 17 ) is held in a closed condition of fusible material adapted to allow the second contacts to open at a temperature above the operating temperature of the bimetallic switching actuator, the arrangement being such that when the sensor is used in the event of bimetallic failure Switching actuator when opening the first set of switch contacts, the second set of switch contacts in response to the melting of the element of fusible material can be opened. Contact heat sensor according to claim 1, wherein the bimetallic switching actuator a curved disc bimetal ( 1 ), which is movable by a snap action between oppositely curved configurations, and a push rod ( 2 ) responsive to movement of the circumference of the bimetal to detect the position of a moving contact ( 3 ) of the first set of switch contacts. Contact heat sensor according to claim 2, wherein the element ( 17 ) of fusible material outside the periphery of the bimetal ( 1 ) is arranged. Contact heat sensor according to claim 1, 2 or 3, wherein the electrical conductor ( 5 ) is formed of spring metal and in the cold state of the sensor in which both sets of contacts are closed, by the action of the bimetallic switching actuator at one end and the action of the element of fusible material at an opposite end via a support ( 23 ), wherein bending the spring metal conductor provides the necessary spring force to actuate the two sets of switch contacts. Contact thermal sensor according to claim 1, wherein the spring-loaded electrical conductor is an elongated electrical spring metal conductor ( 5 ), wherein the one end of the conductor has a first movable contact ( 3 ), which against the Federvorspan contact with a first permanent contact ( 4 ) is held by the bimetallic switching actuator ( 1 . 2 ) which is movable to allow the first contacts to open at a predetermined temperature when the conductor recovers with the movement of the bimetallic switching actuator, and the other end (FIG. 19 ) of the conductor comprises a second movable contact, which against the spring bias of the conductor in contact with a second fixed contact ( 23 ) is held by the element ( 17 ) of fusible material adapted to soften or melt at a temperature above the operating temperature of the bimetallic switching actuator so as to allow the conductor to snap back and open the second contacts, the arrangement being such that, in use of the Sensor in the case of failure of the bimetallic switching actuator when opening the first set of switch contacts, the second set of switch contacts in response to the melting of the element of fusible material can be opened. Contact heat sensor according to claim 5, wherein the electrical spring metal conductor ( 5 ) within an electrically insulating sensor body ( 7 ) is received without attachment to the body and the effect of the bimetallic switching actuator ( 1 . 2 ) at one end of the conductor and the element ( 17 ) of fusible material at the other end serves to load the conductor, at least when the sensor is in use. Contact heat sensor according to claim 6, wherein the action of the bimetallic switching actuating element ( 1 . 2 ) and the element ( 17 ) of fusible material at opposite ends of the electrical spring-metal conductor ( 5 ) serves the conductor via a support ( 23 ) to bend. Contact thermal sensor according to claim 7, wherein the arrangement is such that the through the bent electrical spring metal conductor ( 5 ) spring force developed over the element of fusible material is greater than that developed with respect to the bimetallic switching actuator. Contact heat sensor according to claim 8, wherein the difference in the electrical spring metal conductor ( 5 ) relative to the bimetallic switching actuator ( 1 . 2 ) and the element ( 17 ) spring force developed by fusible material by arranging the support ( 23 ) is reached farther from the one end of the conductor than from the other end thereof. Contact heat sensor according to claim 7, 8 or 9, wherein the support ( 23 ) is formed as part of the second fixed contact. Contact heat sensor according to one of claims 5 to 10, wherein the element of fusible material comprises a push rod ( 17 ), which on the other end of the electrical spring metal conductor ( 5 ) acts. Contact heat sensor according to claim 11, wherein the fusible push rod ( 17 ) is arranged such that when using the sensor with a heating element, an end portion of the push rod abuts directly on the heating element and juxtaposing the sensor with the heating causes the push rod is driven into the sensor, so as to cause the electrical spring metal -Ladder ( 5 ) is charged. Contact heat sensor according to one of claims 5 to 12, wherein in a body part of the sensor an upright element ( 22 ), wherein the upright member serves as a support for interaction with the electrical spring metal conductor during opening of the second set of switch contacts. Contact heat sensor according to claim 13, wherein the arrangement is such that the upright element ( 22 ) in the normal state of the sensor with clearance to the electrical spring metal conductor ( 5 ) and only in response to actuation of the element ( 17 ) of fusible material to open the second set of switching contacts is active. Contact heat sensor according to one of claims 5 to 14, wherein the sensor comprises a sensor body part ( 7 ) provided with a thermally conductive metal cap ( 9 ), and a bimetal ( 1 ) of the bimetallic switching actuator between the cap and the sensor body part, the cap being shaped to form a support ( 11 ) defined with the bimetallic switching actuator. Contact heat sensor according to claim 15, wherein the cap ( 9 ) is deformable to adjust the operation of the bimetallic switching actuator the position of the support ( 11 ). Contact heat sensor according to claim 1, comprising a body part ( 7 ), in which spaced first and second electrical connection parts ( 16 . 13 ), wherein the spring-loaded electrical conductor ( 5 ) interconnects the interposed electrical connection parts, wherein the spring-loaded electrical conductor against its spring bias at one end by means of the bimetallic switching actuator ( 1 . 2 ), which by a push rod ( 2 ), and at the other end by means of an element ( 17 ) is made of fusible material, the arrangement being such that the actuation of the bimetallic switching actuator ( 1 . 2 ) at a predetermined temperature, the one end of the bridge element from the electrical contact with the first electrical connection part ( 16 ) and, in the event of failure of such a mechanism, the melting of the element ( 17 ) of fusible material at a temperature above the predetermined temperature, the other end of the bridge element from the electrical contact with the second electrical connection part ( 13 ) can release. A contact heat sensor according to claim 17, wherein the push rod (14) operating at the one end of the bridge element 2 ) and the element operating at the other end of the bridge element ( 17 ) of fusible material, the bridge element against its own elasticity via a support ( 23 ) to bend. Contact heat sensor according to claim 18, wherein the support ( 23 ) as part of the second electrical connection part ( 13 ) is shaped. Contact heat sensor according to claim 18 or 19, wherein the support ( 23 ) is not arranged with uniform spacing between the opposite ends of the bridge element, so that on one of the components push rod ( 2 ) and element ( 17 ) is made of fusible material, a greater spring force than on the other.