Patent Publication Number: US-5021915-A

Title: Combination starter-protector device and method of assembling same, overload protector and method of assembling same

Description:
FIELD OF THE INVENTION 
     This invention relates in general to electrical controls and in particular to a combination starter-protector device adapted for connection in circuit relation with a dynamoelectric machine, a method of assembling a combination starter-protector device, an overload protector for use in a combination starter-protector device, and a method of assembling an overload protector. 
     BACKGROUND OF THE INVENTION 
     In the past various different combination starter-protector devices and overload protectors for use in such devices have been utilized in circuit relation with a winding circuit of a dynamoelectric machine, such as for instance an electric motor. At least some of the past combination starter-protector devices utilized a positive temperature coefficient resistor (hereinafter sometimes referred to as a PTCR) which was operable generally to at least impede current flow to a start or auxiliary winding means of the electric motor generally as the electric motor was energized to its preselected running or synchronous speed. In some of the aforementioned combination starter-protector devices, an overload or overload protector was thermally coupled with the PTCR and subjected to the current in at least a run or main winding means of the electric motor. Of course, the overload was operable to interrupt the current flow to the electric motor in the event of the occurrence of a winding circuit overload condition which may have had a deleterious affect on components of the electric motor, such as for instance burning-out of the winding circuit. It is believed that in others of the past combination starter-protector devices, the overload may not have been thermally coupled with the PTCR. 
     U.S. Pat. No. 4,319,299 issued Mar. 9, 1982 to Lee O. Woods and Donald L. Haag, U.S. Pat. No. 4,131,871 issued Dec. 26, 1978 to Lee O. Woods and Donald L. Haag, U.S. Pat. No. 4,084,202 issued Apr. 11, 1978 to Donald H. Stoll, U.S. Pat. No. 4,042,860 issued Aug. 16, 1977 to Lee O. Woods and James P. Frank, and U.S. Pat. No. 4,037,316 issued July 26, 1977 to Donald H. Stoll illustrate some of the above discussed past combination starter-protector devices, as well as the operations thereof, in circuit relation with a winding circuit of an electric motor. 
     The past combination starter-protector devices were associated in various manners with various types of electric motors and other apparatus, such as for instance air conditioners or refrigerators having compressor units or the like which utilized hermetic electric motors. In many of these compressor units, a Fusite plug or the like was mounted through a housing or jacket of such compressor units, and such Fusite plug contained a plurality of male terminals connected internally of the compressor housing with the winding circuit of the hermetic electric motor. At least some of the past combination starter-protector devices, such as for instance those illustrated in the aforementioned patents, were associated in electrical mounting or plug-on engagement with the male terminals of the Fusite plug exteriorly of the compressor housing. Of course, some of the past starter devices were of both the plug-on and plug-in type, as illustrated in U.S. Pat. Nos. 3,921,117 and 3,955,170, respectively. In some other installations, it is believed that at least the starter device was electrically interconnected by a plurality of leads having quick-connect terminals which were associated with electric motor terminals so as to be &#34;hung&#34; therefrom. 
     SUMMARY OF THE INVENTION 
     In general, a combination starter-protector device in one form of the invention and adopted for connection in circuit relation with a dynamoelectric machine has a casing with a plurality of wall means for defining a set of chambers and a channel in said casing with the channel communicating with one of the chambers. A set of first terminal openings is provided in one wall means, and two of the first terminal openings intersect another of the chamber chamber while another first terminal opening intersects the channel. Sets of second and third terminal openings are provided in another of the wall means, the second terminal openings intersecting with the another chamber, one third terminal opening intersecting one second terminal opening, and another third terminal opening intersecting the one wall means adjacent a third one of the wall means. A PTCR having a pair of opposite contact surfaces is disposed in the another chamber, and a pair of means is provided for supporting the PTCR in the another chamber. Each supporting means includes means for engagement in circuit relation with a respective one opposite contact surface and a set of resilient means engaged with the casing for urging the respective one engagement means into the circuit relation with the respective one opposite contact surface, respectively. A set of first female terminals is provided on each supporting means with one first female terminal on each supporting means being respectively disposed in the second terminal openings and another first female terminal on each supporting means being respectively aligned with one of the two first terminal openings and the third first terminal opening, and a first male terminal extending from the one first female terminal on one supporting means is received in the one third terminal opening. An overload protector disposed in a third chamber includes a conductive support seated against the casing in the third chamber, a third male terminal on the support extending through the third wall means and received in the another third terminal opening, and conductive means for extension through the third wall means between the one and third chambers. Means disposed in both the channel and one chamber for connection in circuit relation with the conductive means includes a third female terminal aligned with the other of the two first terminal openings. 
     Also in general and in one form of the invention, a method is provided for assembling an overload protector for use in a starter-protector device adapted to be associated in circuit relation with a dynamoelectric machine. The overload protector has a casing, a conductive support with a bimetal switch element secured thereto, and a conductive member having a contact section and a terminal section. The casing includes a sidewall and a base wall defining an open ended recess, at least one slot in the sidewall intersecting the casing, and an extension wall extending from the sidewall therebeyond. In practicing the method, the conductive member is extended through the at least one slot, and the contact section is located within the open ended recess at least adjacent the base wall while the terminal section is located on the extension wall. The terminal section is secured to the extension wall against displacement. The support is disposed in an assembly position at least in part within the open ended recess, and the bimetal switch element is engaged in circuit relation with the contact section. 
     Further in general and in one form of the invention, a method is provided for assembling a combination starter-protector device adapted to be associated in circuit relation with a dynamoelectric machine. The device has a connection strap defining a pair of female terminals, a conductive member having a contact section and a terminal section, a terminal post, an overload protector, and a set of casing members. The overload protector includes a conductive support with a bimetal switch element pivotally mounted thereto. One casing member includes a sidewall and a base wall defining an open ended recess, and an extension wall extending generally laterally beyond a part of the sidewall, and another extension wall on another casing member extending therebeyond. In practicing this method, the contact section of the conductive member is located within the open ended recess in the casing member, and the terminal section of the conductive member is located on the first named extension wall. The terminal post is interconnected with the first named extension wall and the terminal section, and at least the terminal section is retained against displacement. The conductive support is mounted at least in part within the open ended recess against displacement therefrom, and the bimetal switch element is biased into contacting engagement in circuit relation with the contact section. After one female terminal on the connecting strap is received in circuit relation on the terminal post, the one casing member and a third casing member are arranged at least adjacent each other in assembly positions, respectively, and the connection strap is pivoted about the terminal post to place the other female terminal on the connecting strap in a preselected position on the third casing member. The another casing member is placed in an assembly position in overlaying engagement with the third casing member, and the another extension wall is positioned at least adjacent the sidewall and at least in part in overlaying engagement with the first named extension wall. The one aperture in the another casing is aligned with the other female terminal in its preselected position, and the connection strap is enclosed within the casing members when in the assembly positions thereof. Thereafter, when in their assembly positions, the casing members are secured against displacement from each other. 
     Still further in general and in one form of the invention, an overload protector is provided for use in a combination starter-protector device adapted to be associated in circuit relation with a dynamoelectric machine. The overload protector has a casing including a sidewall and a base wall defining an open ended recess in the casing, at least one slot in the sidewall intersecting the open ended recess, and another wall extending beyond the sidewall exteriorly of the open ended recess. A conductive member extending through the at least one slot has a contact section disposed in the open ended recess at least adjacent the base wall and a terminal section seated at least in part on the another wall. Means is provided for securing the terminal section against displacement from the another wall, and bimetal switch means disposed within the open ended recess is operable generally for switching between one position engaged in circuit relation with the contact section and another position displaced from the contact section. Conductive means is disposed at least in part within the open ended recess for supporting the bimetal switch means. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is an exploded perspective view showing a combination starter-protector device and an overload protector respectively in one form of the invention and illustrating principles which may be practiced in respective methods of assembling such device and such overload protector also in one form of the invention; 
     FIG. 2 is a top elevational of the overload protector of FIG. 1, with parts thereof broken away; 
     FIGS. 1 and 4 are sectional views taken along lines 3--3 and 4--4 in FIG. 2, respectively; 
     FIG. 5 is a partial top elevational view illustrating an alternative overload protector in one form of the invention with parts thereof removed for simplicity of disclosure; 
     FIG. 6 is a partial sectional view taken along lines 6--6 in FIG. 5; 
     FIG. 7 is a top elevational view of the combination starter-protector device of FIG. 1 with part of the casing removed; 
     FIGS. 8, 9 and 10 are sectional views taken along lines 8--8, 9--9 and 10--10 in FIG. 7, respectively; 
     FIG. 11 is a schematic diagram of an exemplary circuit illustrating the combination starter protector device connected in circuit relation with a winding circuit of a dynamoelectric machine arranged within an apparatus housing; and 
     FIG. 12 is an exemplary graphical representation illustrating the relationship of the temperature and resistance characteristics of a PTCR. 
     Corresponding reference characters indicate corresponding parts throughout the several views of the drawings. 
     The exemplifications set out herein illustrate the preferred embodiments of the invention in one form thereof, and such exemplifications are not to be construed as limiting in any manner either the scope of the disclosure or the scope of the claims which follow. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     Referring now to the drawings in general, there is illustrated in one form of the invention a method of assembling an overload or overload protector 21 for use in a combination starter-protector device 23 adapted to be associated or connected in circuit relation with a dynamoelectric machine, such as for instance a hermetic electric motor 25 or the like (FIGS. 1-6 and 11). Overload 21 is provided with a casing or casing member 27 which may be formed of a dielectric material, such as a resin or the like for instance, a conductive support or supporting means 29 with a bimetal switch element or switch means 31 secured thereto, and a conductive member 33 having a contact section 35 and a terminal or mounting section 37 (FIGS. 1-3). Casing 27 includes a sidewall 39 and a base wall 41 defining an open ended recess 43 in the casing, a slot 45 in the sidewall intersecting with the open ended recess, and an extension wall 47 extending from the sidewall exteriorly of the open ended recess (FIGS. 1 and 2). In the practice of this method, conductive member 33 is extended or passed through slot 45, and contact section 35 of the conductive member is located within open ended recess 43 in casing 27 at least adjacent base wall 41 while terminal section 37 of the conductive member is located or seated in abutment on extension wall 47 (FIGS. 1 and 2). Upon the location of terminal section 37, it is secured against displacement to extension wall 47 by suitable means, such as for instance a terminal post 49 or the like (FIG. 4). Thereafter, conductive support 29 is disposed or positioned at least in part within open ended recess 43, and bimetal switch element 31 on the support is engaged in circuit relation with contact section 35 of conductive member 33 (FIGS. 1 and 3). 
     More particularly and with specific reference to FIGS. 1-4, a pair of mounting openings or apertures 51, 53 are provided through terminal section 37 of conductive member 33 and extension wall 47 of casing 27, respectively. During the aforementioned location of terminal section 37 on extension wall 47, mounting opening 51 in the terminal section and mounting opening 53 in the extension wall are aligned with each other, as shown in FIG. 4. When mounting openings 51, 53 are so aligned with each other, a mounting end or end portion 55 on terminal post 49 is passed or extended through the aligned mounting openings to seat a flange 57 on the terminal post generally about mounting opening 51 of the terminal section in circuit relation therewith. Upon the seating of terminal post flange 57 against terminal section 37 of conductive member 33, a distal end 59 on mounting end portion 55 of terminal post 49 is swedged or otherwise deformed into displacement preventing engagement with extension wall 47 generally about mounting opening 53 therein. Thus, the above disclosed engagement of deformed distal end 59 of terminal post 49 with extension wall 47 and terminal post flange 57 with terminal section 37 of conductive member 33 not only retains the terminal post in an assembly position against displacement from aligned mounting openings 51, 53 but also retains the conductive member at least in part in an assembly position on the extension wall against displacement therefrom. With terminal post 49 so mounted in its assembly position, a female terminal receiving end or end portion 61 of the terminal post extends generally opposite mounting end portion 55 and generally perpendicularly from terminal section 37 of conductive member 33. If desired, extension wall 47 of casing 27 may be provided with a locating or seating surface or abutment 63 to engage a cooperating marginal surface, such as for instance a notch 65 or the like, in terminal section 37 of conductive member 33 thereby to assist in the location of the conductive member in its assembly position, as discussed above and as best seen in FIG. 2. Furthermore, during the location of conductive member 33 in its assembly position on casing 27, a male terminal 67 integrally formed on terminal section 37 so as to extend therefrom is positioned or disposed in a terminal slot 69 at least partially provided therefor in extension wall 47. 
     Casing 27 is additionally provided with another slot 71 in sidewall 39 intersecting open ended recess 43 and spaced from slot 45, and both slots 45, 71 also intersect with a marginal edge 73 on the casing extending about the open ended recess, as best seen in FIG. 2. As best seen in FIGS. 2 and 3, a plurality of seating surfaces or abutments 75 are also provided on sidewall 39 extending into open ended recess 43 for positioning engagement with cooperating abutment parts 77 on conductive support 29 upon the assembly thereof with casing 29, as discussed hereafter. 
     When conductive support 29 is assembled with casing 27, the conductive support is passed or entered into open ended recess 43 past marginal edge 73 on the casing, and abutment parts 77 on the conductive support are seated in abutment with seating surfaces 75 on sidewall 39 within the open ended recess thereby to locate the conductive member in a preselected or assembly position within the open ended recess. To retain conductive support 39 against displacement from its assembly position within open ended recess 43, a hardenable adhesive material (not shown) is hardened in place between a part of the conductive support and sidewall 39 of casing 27. While conductive support 29 is disclosed as being retained against displacement from its assembly position in open ended recess 43 by a hardenable adhesive material, as discussed above, it is contemplated that as an alternative construction, a part of the conductive support could be staked in place to casing 29 within the scope of the invention; however, such alternative construction is not shown for the purposes of drawing simplification and brevity of disclosure. 
     A male or line terminal 79 is connected in circuit relation with conductive support 29 by suitable means, such as for instance a spot wild or the like (not shown), and during the entrance of the conductive support into its assembly position in open ended recess 43, the male terminal is passed or extended through slot 71 in sidewall 39 of casing 29 to be received or positioned in another terminal opening or slot 81 provided at least in part in extension wall 47 adjacent terminal opening 69, as best seen in FIGS. 1 and 2. Of course, terminal openings 69, 81 are isolated from each other. 
     Bimetal switch element 31 is heat sensitive and heated in response to current flow therethrough (as discussed in greater detail hereinafter) for discrete snap action movement between a stable configuration thereof, as well known to the art, and as best seen in FIG. 3, the bimetal switch element has a part thereof pivotally mounted or secured in circuit relation to conductive support 29 by suitable means, such as for instance a weld slug or the like. Since bimetal switch element 31 is mounted to conductive support 29, the bimetal switch element is conjointly entered with the conductive support into open ended recess 43, and when the conductive support is located in its assembly position within the open ended recess, as previously discussed, a movable contact 83 carried on the bimetal switch element is engaged or contacted in circuit relation with a stationary contact 85 on contact section 35 of conductive member 33. Thus, when movable and stationary contacts 83, 85 are in circuit making engagement, bimetal switch element 31 is disposed in its stable configuration and biased or resiliently stressed between conductive support 29 and contact section 35 of conductive member 33. 
     An adjusting screw 87 is passed or inserted through an aperture or opening 89 in conductive support into threaded or adjusting engagement with another aperture or opening 91 in base wall 41 of casing 29. A head 93 on adjusting screw 87 is urged into adjusting engagement with conductive support 29 generally about aperture 89 therein to exert an adjusting force onto the conductive support in response to the threaded engagement of the adjusting screw with base wall aperture 91. To complete the description of the method of assembling overload protector 21, conductive support 29 yields at least in part generally at a yieldable section 93a adjacent aperture 89 in the conductive support in response to the adjusting force exerted or applied thereon by adjusting screw 87, and in response to such yielding of the yieldable section, the adjusting force is transferred through the conductive support to bimetal switch element 31 adjusting its bias effecting the contacting engagement of movable and stationary contacts 83, 85. 
     With reference again to the drawings in general and recapitulating at least in part with respect to the foregoing, overload protector 21 in one form of the invention is illustrated for use in combination starter-protector device 23 adapted to be associated in circuit relation with dynamoelectric machine (FIGS. 1-6 and 11). Overload protector 21 is provided with casing 21 having sidewall 39 and base wall 41 defining open ended recess 43 in the casing (FIGS. 1 and 2). Slot 45 in sidewall 39 intersects open ended recess 43, and extension wall 47 of casing 21 extends beyond the sidewall exteriorly of the open ended recess (FIGS. 1 and 2). Conductive member 33 extends through slot 45 and includes contact section 35 disposed in open ended recess 43 at least adjacent base wall 41 and terminal section 37 seated at least in part on extension wall 47 (FIGS. 1-3). Means, such as for instance mounting end portion 55 and flange 57 of terminal post 49 or the like, is provided for securing terminal section 37 against displacement from extension wall 47 (FIG. 4). Bimetal switch means or element 31 disposed within open ended recess 43 is operable generally for switching between one position engaged in circuit relation with contact section 35 and another position displaced from the contact section (FIG. 3). Conductive means or support 29 is disposed at least in part within open ended recess 43 for supporting bimetal switch element 43 therein (FIGS. 2 and 3). 
     In the operation of overload protector 21 with is component parts in the above described positions thereof, assume that a current is passed through the overload protector from male or line terminal 79 to terminal post 49. Thus, the current passes from male terminal 79 through conductive support 29, bimetal switch element 31 and movable and stationary contacts 83, 85 in their circuit making engagement and therefrom through conductive member 33 to terminal post 49. As previously mentioned, bimetal switch element 31 is operable in response to heat generated by the current flowing therethrough. Therefore, in the event of the occurrence of a high resistance to the current flow, the value of the current is increased thereby to heat bimetal switch element 31 to a preselected temperature which effects the discrete snap action movement of the bimetal switch element from its at-rest position or stable configuration, i.e. when movable contact 83 is biased into circuit making engagement with stationary contact 85, into the actuated position or unstable configuration of the bimetal switch element thereby to displace or break the movable contact 83 from the stationary contact 85. Of course, when bimetal switch element 31 is so actuated to break movable contact 83 from engagement with stationary contact 85, the circuit through overload protector 21 between male terminal 79 and terminal post 49 is interrupted or broken. When the aforementioned high resistance to the current flow is alleviated, bimetal switch element 31 cools to a temperature less than the preselected temperature which effects the return discrete snap action movement of the bimetal switch element from its unstable configuration to its stable configuration. To complete the description of the operation of overload protector 21, movable contact 83 is reengaged with stationary contact 85 in response to the return discrete snap action movement of bimetal switch element 31 into its stable configuration thereby to reestablish the circuit through the overload protector between male terminal 79 and terminal posts 49. 
     An alternative overload protector 21a and an alternative assembling method therefor are illustrated in FIGS. 5 and 6 in one form of the invention, respectively with the alternative overload protector and assembling method utilizing generally the same component parts functioning and assembled generally in the same manner as previously described with respect to overload protector 21 and its assembly method with the following exceptions. A conductive member 33a includes a contact section 35a and a terminal section 37a, and a resistance heating elements 95 is interconnected in circuit relation between terminal section 37a and a mounting or supporting terminal 97 for a stationary contact 85a by suitable means, such as for instance welding or the like (not shown). 
     Subsequent to the aforementioned interconnection or assembly of contact section 35a with terminal section 37a, conductive member 33a is disposed in its assembly position on casing 35. In this assembly position, contact section 35a is disposed within open ended recess 43 of casing 27, and supporting terminal 97 is mounted against displacement in another opening 99 therefor in base wall 41 of casing 27 by suitable means, such as for instance swedging or the like, thereby to dispose stationary contact 85a at least adjacent the base wall for engagement with movable contact 83 on bimetal switch element. Of course, when conductive member 33a is disposed in its assembly position, as discussed above, terminal section 37a is secured against displacement to extension wall 47 by terminal post 49 in the same manner discussed hereinabove with respect to conductive member 33. To complete the description of alternative overload protector 21a and its assembling method, heat generated by resistance heating element 95 in response to current flow therethrough is transferred to bimetal switch element 31 to assist in effecting the discrete snap action movement of the bimetal switching element from the stable configuration to the unstable configuration thereof in the same manner as previously discussed hereinabove. 
     With further reference in general to FIGS. 1-11, there is provided a method in one form of the invention for assembling starter-protector device 23 adapted to be associated in circuit relation with dynamoelectric machine 25, and since overload protector 21 is an integral component of the combination starter-protector device, the method steps involved in the above discussed method of assembling the overload protector are preliminary to the method steps involved in the method of assembling the combination starter-protector device, as discussed in detail hereinbelow. 
     Along with casing 27 of overload protector 21, combination starter-protector device 23 is also provided with a pair of mating casings or casing members 111, 111a which may also be formed of a suitable dielectric material, such as a resin or the like for instance, as best seen in FIGS. 1 and 7, and for purposes of brevity of disclosure, like parts of casing 111a corresponding to those of casing 111 will be designated by the letter &#34;a&#34;. Casings 111, 111a are provided with a plurality of walls or wall means, indicated generally at 113, 113a, which include marginal walls or sidewalls 115, 115a and cross walls 117, 117a integrally connected across the marginal walls, respectively. Casing 111a is additionally provided with another extension wall 119 which extends generally laterally beyond marginal wall 115a and a set of Fusite pin receiving apertures 121, 123, 125 which extend in a preselected clustered formation through cross wall 117a, respectively. 
     When casings 111, 111a are associated in assembly positions in overlaying and mating engagement with each other, as discussed in greater detail hereinafter, each casing defines in part a channel 127 and a chamber 129 which are separated or isolated from each other and also a set of female terminal receiving openings or slots 131, 133 which intersect or communicate with chamber 129 and marginal walls 115, 115a of the casings, respectively, as best seen in FIGS. 1 and 7. Each casing 111, 111a further defines in part a male terminal receiving opening or slot 135 which intersects or communicates with female terminal receiving slot 131 and marginal walls 115, 115a, and male terminal opening 135 is arranged to be disposed in side-by-side relation with terminal slot 69 in extension wall 47 of casing 27 when casing 27 is arranged in assembly relation with casing 111, as discussed hereinafter. 
     Subsequent to the above discussed assembly of overload protector 21, casing 27 of the overload protector and casing 111 are arranged at least adjacent each other in assembly positions, as best seen in FIG. 7. With casings 27, 111 in their assembly positions, a female terminal 137 integrally formed on a conductive connection strap 139 is placed or received in circuit relation about terminal end portion 61 of terminal post 49 on casing 27, and the connection strap is moved or pivoted about the terminal post to place another female terminal 141 integrally formed on the connection strap generally opposite female terminal 137 in a preselected position on casing 111. When female terminal 141 is so located in its preselected position, it may be noted that connection strap 139 is disposed or extends in part within the portion of channel 127 defined by casing 111, and female terminal 141 in its preselected position is also located in such channel portion. 
     Combination starter-protector device 23 also utilizes a pair of means, such as for instance pressure plate 143, 143a or the like, for supporting or embracing a PTCR 145 having a pair of generally opposite contact surfaces 147, 147a. Pressure plates 143, 143a may be formed of any suitable material having the desired electrical and physical properties, such as for instance a stainless steel or the like, and for purposes of brevity of disclosure, like parts of pressure plate 143a corresponding to those of pressure plate 143 are designated by the letter &#34;a&#34;. Pressure plates 143, 143a have generally central or contact portions or sections 149, 149a with a set of means, such as for instance nodes 151, 151a or the like, for contacting or engagement in circuit relation with opposite contact surfaces 147, 147a on PTCR 145, respectively. A set of resilient means, such as for instance spring fingers 153, 153a or the like, are integrally formed with central portions 149, 149a and extend generally radially therebeyond, and a pair of arms 155, 157 and 155a , 157a on the central portions extend therebeyond to define female terminals 159, 161 and 159a, 161a, respectively. It may be noted that arm 155a also defines a male terminal 163 extending at least in part generally opposite female terminal 159a. 
     Subsequent to the above discussed placement of female terminal 141 of connection strap 139 in the preselected position thereof on casing 111, pressure plate 143 may be disposed or positioned in that part of chamber 129 defined in casing 111 with the distal ends of spring fingers 153 respectively engaged with cross wall 117, and female terminal 159 is received in that part of terminal opening 133 defined by casing 111 while female terminal 161 is located in a preselected position therefor at least adjacent cross wall 117. With pressure plate 143 located in an assembly position on casing 111, as discussed above, opposite contact surface 147 on PTCR 145 is placed in contacting engagement with nodes 151 on central portion 149 of pressure plate 143, and pressure plate 143a is then located with respect to casing 111 to place nodes 151a on central portion 149a in contacting engagement with opposite contact surface 147a on the PTCR. Upon the association of pressure plate 143a with PTCR 145, as discussed above, female terminal 159a is received in that part of terminal opening 131 defined by casing 111 while female terminal 161a is located in a preselected position therefor at least adjacent cross wall 117. Further, male terminal 163 on pressure plate 143a is received in that part of male terminal opening 135 defined in casing 111. With pressure plate 143a located in its assembly position on casing 111 and PTCR 145, as discussed above, it may be noted that spring fingers 153a of pressure plate 143a are respectively disposed in opposed overlaying spaced apart relation with spring fingers 153 of pressure plate 143. Furthermore, while arms 157, 157a are illustrated herein as being connected by suitable means, such as for instance spot welding or the like (not shown), to central portions 149, 149a of pressure plates 143, 143a, it is contemplated that such arms 155a, 157a may be integrally formed with central portions 149, 149a within the scope of the invention. While pressure plates 143, 143a and PTCR 145 are discussed above as being assembled onto casing 111 subsequent to the association of connection strap 139 with terminal post 49 and casing 111, it is contemplated that such assembly of the pressure plates and PTCR onto casing 111 may occur prior to the association of the connection strap with the terminal post and casing 111 within the scope of the invention. Furthermore, it is also contemplated that PTCR 145 may be embraced between pressure plates 143, 143a with the assembled together pressure plates and PTCR being thereafter located on casing 111 in the positions discussed hereinabove within the scope of the invention. 
     Subsequent to the location of pressure plates 143, 143a and PTCR 145 in their respective assembly positions on casing 111, as discussed above, casing 111a is associated or arranged in an assembly position with respect to both casings 27, 111. When casing 111a is located in its assembly position, marginal walls 115a on casing 111a are engaged or mated at least in part with marginal walls 115 on casing 111, and cross walls 117, 117a of casings 111, 111a are disposed in opposed overlaying spaced apart relation with each other, respectively. As previously discussed parts of channel 127, chamber 129, female terminal receiving openings 131, 133 and male terminal receiving slot 135 are defined by both casings 111, 111a, and when casings 111, 111a are located in their assembly positions, channel 127, chamber 129, female terminal openings 131, 133 and male terminal slot 135 are enclosed or formed between casings 111, 111a. Thus, pressure plates 143, 143a with PTCR 145 embraced therebetween are enclosed within chamber 129, and female terminals 159, 159a on the pressure plates are received or disposed within female terminal openings 131, 133 while male terminal 163 on pressure plate 143a is received or disposed within male terminal slot 135. Further, with casings 111, 111a in their assembly positions, it may be noted that channel 127 is separated or isolated from chamber 129, and in their respective preselected positions on casing 111, female terminal 141 of connection strap 139 and female terminals 161, 161a on arms 157, 157a of pressure plates 143, 143a are respectively aligned with apertures 121, 123, 125 in cross wall 117a of casing 111a. Additionally, a plurality of mating sections or parts 165, 165a on casings 111, 111a  are entered into capturing or locating relation or engagement with female terminals 141, 161, 161a to retain the female terminals against displacement from their preselected positions in alignment with apertures 121, 123, 125 when casings 111, 111a are in their assembly positions, respectively. It may also be noted that the distal ends of spring fingers 153a on pressure plates 143a are biased into engagement with cross wall 117a of casing 111a urging nodes 151a toward contacting engagement with opposite contact surface 147a of PTCR 145, and in response thereto, opposite contact surface 147 of the PTCR is urged into contacting engagement with nodes 151 of pressure plate 143 against the bias of spring fingers 153 engaged with cross wall 117 of casing 111. Thus, when casings 111, 111a are in their assembled positions, PTCR 145 is biased in contacting engagement between pressure plates 143, 143a in response to the resilient or biasing engagement of spring fingers 153, 153a with cross walls 117, 117a of casings 111, 111a, respectively. 
     When casing 111a is arranged in its assembly position with respect to both casings 27, 111, as discussed above, extension wall 119 on casing 111a is disposed at least adjacent sidewall 39 of casing 27 and in overlay mating engagement with extension wall 47 of casing 27. With extension walls 47, 119 so disposed in their assembly positions as described above, another chamber 167 is defined between the extension walls and sidewall 39 of casing 27, and it may be noted that chamber 167 communicates with channel 127 while being separated or isolated from chamber 129. Thus, terminal section 37 of conductive member 33 is at least in part enclosed within chamber 167 along with a part of connection strap 139 with its female terminal 137 engaged on terminal post 49, and as previously mentioned, the connection strap also extends in part through channel 127 with female terminal 141 on the connection strap being aligned with aperture 121 in cross wall 117a of casing 111. 
     Male terminal slots 69, 81 are in part defined by each extension wall 47, 119 so as to be closed or formed when the extension walls are disposed in their assembly positions, and male terminals 67 on conductive member 33 and male terminal 79 on conductive support 29 are respectively positioned in male terminal slots 69, 81 when the extension walls are in their assembly positions. It may also be noted that extension wall 119 has a flange 169 depending therefrom and which is extended at least in part within slot 45 in sidewall 39 of casing 27 thereby to at least in part isolate open ended recess 43 in casing 27 from chamber 167. Upon the closure of male terminal slots 69, 81, as discussed above, it may be noted that male terminal slots 69, 81, 135 are arranged adjacent each other in side-by-side relation with male terminals 67, 79, 163 disposed therein so as to conveniently receive in circuit relation a plug-in multiple connector of a type well known to the art (not shown). To complete the description of the method of assembling combination starter-protector device 23, suitable securing means, such as for instance a plurality of rivets 171 or the like, may be interconnected in displacement preventing engagement between casings 29, 111, 111a thereby to maintain the casings in their assembly positions with respect to each other. While rivets 171 are disclosed herein for maintaining casings 27, 111, 111 a against displacement from their assembly positions, it is contemplated that other securing means, such as for instance laser welding of the casings against displacement (not shown), may be utilized within the scope of the invention. 
     In the light of the foregoing discussion with respect to the method of assembling combination starter-protector device 23, it is believed that such discussion also illustrates the combination starter-protector device per se in one form of the invention. 
     In the exemplary schematic diagram of a circuit 173 in FIG. 11, a start or auxiliary winding 175 and a main or run winding 177 are shown connected in circuit configuration in a winding circuit 179 for dynamoelectric machine 25, and a dielectric plug device 181, such as a Fusite plug or the like for instance, is mounted to a housing or jacket 183 of an apparatus 185, such as a hermetic compressor or the like for instance which may be of the type utilized in refrigeration or air conditioning systems (not shown). Plug device 181 has three pin terminals 187, 189, 191, and pin terminals 187, 189 are respectively connected in circuit relation with start and run windings 175, 177 while pin terminal 191 is connected in circuit relation with both the start and run windings. Combination starter-protector device 23 is mounted in plug-on relation to plug device 181, and female terminals 141, 161, 161a of the combination starter-protector device are releasably received on terminal pins 187, 189, 191 in electrical conductive plug-on or contacting relation therewith to associate the combination starter-protector device in circuit relation with winding circuit 179 of dynamoelectric machine 25. A pair of leads 193, 195 are respectively connected between a pair of power or line terminals L1, L2 and male terminals 67, 163 of combination starter-protector device 23, respectively. A dynamoelectric machine or motor control, such as an on-off switch 197 or the like for instance, may be interposed in lead 193, and if desired, a capacitor 199 may be interconnected in plug-in circuit relation with female terminals 159, 159a on pressure plates 143, 143a of combination starter-protector device 23. To complete the description of exemplary circuit 173, a fan motor 201 utilized in the aforementioned refrigeration or air conditioning systems (not shown) is interposed in a lead 203 interconnected between lead 195 and male terminal 67 on conductive member 33 of combination starter-protector device 23. 
     In the operation of combination starter-protector device 23 when connected in the exemplary circuit 173, as discussed above, an operator may energize dynamoelectric machine 25 across line terminals L1, L2 by closing switch 197. With switch 197 closed, power is supplied from line terminal L1 through the closed switch, lead 193, male terminal 67 on conductive support 29 of combination starter-protector device 23, its bimetal switch element 31, conductive member 33, terminal post 49 and connection strap 139 to terminal pin 191 of plug device 181. From terminal pin 191 the current flows through both start and run windings 175, 177 of dynamoelectric machine 25 to terminal pins 187, 189 of plug device 181, and the current passing through the start winding flows from terminal pin 187 through pressure plate 143, PTCR 145, pressure plate 143a and male terminal 163 of combination starter-protector device 23 to lead 195 and line terminal L2. At the same time the current passing through run windings 177 of dynamoelectric machine 25 flows from terminal pin 189 of plug device 181 through pressure plate 143a and its male terminal 163 in combination starter-protector device 23 to line 195 and line terminal L2. When capacitor 199 is connected in circuit relation between female terminals 159, 159a of terminal plates 143, 143a in combination starter-protector device 23, the current flowing through start winding 175 also passes through capacitor 199 to enhance the running characteristics of dynamoelectric machine 25, and of course, fan motor 201 is energized across line terminals L1, L2 upon the aforementioned closure of switch 197. 
     As previously mentioned and as graphically illustrated in FIG. 12, PTCR 145 is operable generally in response to current flow therethrough to increase its resistance generally as a function of temperature; therefore, assuming the temperature of the PTCR to be rather low at the beginning of the start-up period of dynamoelectric machine 25 when switch 197 is closed, the PTCR will initially pass current at a value sufficiently great enough to effect a desired starting torque for the dynamoelectric machine during its start-up period. As the temperature of PTCR 145 increases in response to current flow therethrough to the anomaly or transition temperature of the PTCR, its resistance to such current flow also increases to a value which generally renders start winding 175 ineffective in winding circuit 179 of dynamoelectric machine 25 to as to electrically disassociate the start winding from run winding 177. The point of time during the start-up period of dynamoelectric machine 25 at which start winding 175 may be disabled or rendered ineffective, as previously mentioned, may be predetermined so as to generally coincide with the desired running speed of the dynamoelectric machine. PTCR 145 will not act to obviate current flow through start winding 175, but the PTCR will throttle or restrict the passage of such current flow to such a minimal or small value that the start winding is ineffective in winding circuit 179. Of course, when the operator opens switch 197, circuit 173 is interrupted across line terminals L1, L2, and dynamoelectric machine 25 as well as fan motor 201 are deenergized. 
     As is well known in the art, overload conditions may deleteriously affect components of a dynamoelectric machine, such as for instance shorting or burning-out of the winding circuit thereof, and such overload conditions may be effected by a plurality of different causes or by various combinations of such causes. For instance, some of the well known causes of motor overload conditions are: a running overload; a high temperature overload; an overload occasioned by a stalled or locked rotor; and a high current overload. Irrespective of the particular cause or combination of causes effecting an overload condition, a deleteriously high current is drawn by the dynamoelectric machine, and such high current draw is usually accompanied by or results in a high temperature. Therefore, for the sake of simplifying the discussion of overload conditions herein, it is to be understood that any causes or causes for effecting such an overload condition will be discussed only within the context of a high current draw accompanied by a high temperature condition with respect to winding circuit 179 of dynamoelectric machine 25. 
     In the event of the occurrence of an overload or high current draw condition in dynamoelectric machine 25, a relatively large amount of current may be drawn in circuit 173 which could deleteriously affect start and run windings 175, 177, as previously mentioned. However, bimetal switch element 31 is responsive to the aforementioned high current and temperature increase to correspondingly increase the heat generated by the bimetal switch element so as to effect the discrete snap action movement of the bimetal switch element from the circuit making position or stable configuration to the circuit breaking position or unstable configuration thereof which disengages movable contact 83 from stationary contact 85 as previously discussed. In this manner, circuit 173 is opened effecting the deenergization of dynamoelectric machine 25 as well as fan motor 201 thereby to isolate or electrically disassociate winding circuit 179 of the dynamoelectric machine 25 and that of fan motor 201 from the current overload which may then exist in the dynamoelectric machine across line terminals L1, L2. 
     Of course, the above discussed opening of circuit 173 also effects the deenergization and resultant cooling of PTCR 145, and bimetal switch element 31 may cool sufficiently in its circuit breaking position so as to cycle a plurality of times between its circuit breaking and making positions until the high current draw is alleviated. Upon the alleviation of the high current draw, PTCR 145 cools, and its resistance is correspondingly reduced generally as a function of its decreasing temperature. Thus, when the resistance and temperature of PTCR 145 are reduced to a sufficiently low value, the PTCR will again pass current at a value sufficiently great enough to effect the restarting of dynamoelectric machine 25. Therefore, when bimetal switch element 31 also cools enough to cycle or return to its uninterrupted circuit making position, current is drawn through PTCR 145 to again effect the energization of winding circuit 179 in dynamoelectric machine 25 to bring it up to its predetermined running speed, as discussed hereinabove. At the same time, fan motor 201 is also reenergized across line terminals L1, L2. When dynamoelectric machine 25 is so reenergized to attain its running speed, the self-heating effect of PTCR 145 is again effective to reduce current flow therethrough to a value again rendering start winding 175 ineffective in winding circuit 179 of the dynamoelectric machine. Thus, the restarting of dynamoelectric machine 25 assumes that the cause of the overload condition has been alleviated, and if not so alleviated, combination starter-protector device 23 may again operate or function to open circuit 173 taking the dynamoelectric machine as well as fan motor 201 off the line across line terminals L1, L2, as previously described. 
     When overload protector 21a is utilized in combination starter-protector device 23, the heat generated by resistance heating element 95 is supplemental to that effected by bimetal switching element 31 during the occurrence of an overload condition in dynamoelectric machine 25 to increase the &#34;off-time&#34; of the bimetal switching element, i.e. to increase the length of time the bimetal switching element is cycled into its circuit breaking position. 
     In view of the foregoing, it is now apparent that a novel combination starter-protector device 23, a novel method of assembling such combination starter-protector device, novel overload protectors 21, 21a and a novel method of assembling such overload protectors have been presented, and it is contemplated that changes as to the precise arrangements, configurations, details and connections of the components of such combination starter-protector device and overload protector and also as to the precise order of the method steps of such assembling methods may be made by those having ordinary skill in the art without departing from the spirit of the invention or from the scope of the invention as illustrated in the claims which follow.