CN201323138Y - Electrical switching device and energy storage component thereof - Google Patents
Electrical switching device and energy storage component thereof Download PDFInfo
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- CN201323138Y CN201323138Y CNU2008201798682U CN200820179868U CN201323138Y CN 201323138 Y CN201323138 Y CN 201323138Y CN U2008201798682 U CNU2008201798682 U CN U2008201798682U CN 200820179868 U CN200820179868 U CN 200820179868U CN 201323138 Y CN201323138 Y CN 201323138Y
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Abstract
The utility model relates to an electrical switching device and an energy storage component thereof, in particular to an energy storage component (100) of a breaker (2) used on the electrical switching device. The energy storage component comprises a mounting base (102) which can be detachably connected on a breaker shell (4). An energy storage mechanism, such as a spring (120), is connected on the mounting base, and can move between a loading position and an unloading position. An actuating component (150) can coordinate with gears (132, 134 and 136) of a gear assembly (130) in order to move between a first position and a second position of the loading position and the unloading position corresponding to the spring. A hand loading mechanism (160) and an automatic loading mechanism (170) are connected on the gear assembly, and can move gears for moving the actuating component and loading the spring. The spring, the actuating component, the gear assembly and the loading mechanism are all connected on the mounting base to form a sub assembly (180) which can be detachably connected with the breaker shell.
Description
Technical field
The utility model relates generally to electrical switchgear, relates in particular to be used for for example stored energy assembly of circuit breaker of electrical switchgear.
Background technology
Electrical switchgear, circuit breaker for example can protect electrical system for example to exempt from the electric fault situation of current overload, short circuit, abnormal voltage and the infringement of other failure condition.Usually, circuit breaker comprises operating mechanism, and its response is for example opened electrical contact component by detected these failure conditions of trip unit, with the electric current of interrupt flow through the conductor of electrical system.
The stored energy assembly that some medium voltage breakers for example use spring to control.Specifically, the operating mechanism of these circuit breakers generally includes the assembly of opening with at least one spring of opening (for example separating) that helps electrical contact component, the closing assembly of spring that comprises the some of close electrical contacts assembly, and the load maintainer that is used for loading spring.Come closed contact assembly by discharging closing assembly spring energy stored.By use manual charging mechanism for example charging handle manually the closing assembly spring is loaded, for example perhaps using, load maintainer or other suitable motor machine load maintainer of motor driven automatically load the closing assembly spring.Manually and in the autoloading structure each of known stored energy assembly all needs self independent parts " linkwork " or assembly, so that with the power source of correspondence (manpower for example; Motor power) is attached to the spring that must be loaded.All have a large amount of parts in these assemblies each, the manufacturing of some of them parts is complicated and/or install or assemble difficult.In addition, manually and other parts of the parts of autoloading structure and common stored energy assembly all be " (the built in) of interior dress " usually with respect to circuit breaker.In other words, they are connected to the diverse location on the Shell of circuit breaker individually and can not easily exchange to be used for other application (for example using with other circuit breaker).This causes maintenance, changes and/or safeguards very difficulty of described load maintainer, because this needs whole circuit breaker to be disassembled at least in part.And the charging handle that is used for manual charging mechanism is bigger (for example long, so that leverage is provided) individual components, and it is not forever connected usually, therefore must separate with circuit breaker and deposit, and so just causes it to lose.
Therefore, there are improved space in electrical switchgear such as circuit breaker and stored energy assembly thereof.
The utility model content
Embodiment of the present utility model can satisfy these and other needs, described embodiment is at a kind of for example stored energy assembly of circuit breaker of electrical switchgear that is used for, described stored energy assembly is self-contained (self-contained), and can be common to various application and/or various circuit breaker.
As an aspect of the present utility model, provide a kind of stored energy assembly that is used to comprise the electrical switchgear of housing.This stored energy assembly comprises: the mount pad that is configured to be connected to removedly housing; The stored energy mechanism that is connected to this mount pad and can between loading position and unloading position, moves; The gear assembly that comprises a plurality of gears; Can cooperate with gear so that the actuation element that stored energy mechanism is loaded, this actuation element can move in the primary importance of loading position with between corresponding to the second place of stored energy mechanism in unloading position corresponding to stored energy mechanism; Be connected to first load maintainer of corresponding one of them gear; And second load maintainer that is connected to corresponding one of them gear.In first load maintainer and second load maintainer each is configured to carrier wheel, so that mobile actuation element and stored energy mechanism loaded.Stored energy mechanism, actuation element, gear assembly, first load maintainer and second load maintainer all are connected on the mount pad, thereby form sub-component, and this sub-component is configured to be connected to removedly on the housing of electrical switchgear.
This mount pad can comprise first sidepiece, second sidepiece, first end, be oppositely arranged with first end and away from the second end of first end, being configured to be connected to the rear portion of housing and being configured to can be from the approaching front portion of outside.The installation component that this stored energy mechanism can comprise spring and be configured to spring is installed in second sidepiece of mount pad.Spring can have near the first end the first end of mount pad, the second end that extends towards the second end of mount pad and a plurality of pitch of the laps of extending between the second end of the first end of spring and spring.This installation component can be included in mount pad the first end place or neighbouring from mount pad outward extending first connector of second sidepiece, be connected to second connector of actuation element and the ways that between first connector and second connector, extends.This spring can be between first connector and second connector, and wherein ways extends through pitch of the laps.
First load maintainer can be can be by manual manipulation so that to spring-loaded manual charging mechanism.Second load maintainer can be can operate so that automatically to spring-loaded autoloading structure.Described gear can comprise first gear of second sidepiece that is connected to mount pad, the 3rd gear that is connected to second gear of autoloading structure and is connected to actuation element and can cooperates with first gear and second gear.Manual charging mechanism can be connected to the autoloading structure, and can be configured to mobile autoloading structure so that move second gear.The 3rd gear can comprise the center and overall be circular periphery, and actuation element can comprise planar section with from the vertical outward extending projection of planar section.This planar section can be connected to the 3rd gear, and wherein said projection is at described center and totally be between the periphery of circle.When the 3rd gear is pivoted and actuation element when shifting to primary importance, the projection of actuation element can move second connector with the compression spring along first direction, and, when the 3rd gear is pivoted and actuation element when shifting to the second place, the projection of actuation element can move second connector along the second direction roughly opposite with first direction, so that retracting spring.Manual charging mechanism can comprise charging handle and unilateral bearing, and the autoloading structure can comprise electro-motor.This unilateral bearing can be between charging handle and electro-motor, wherein only when charging handle when a predetermined direction moves, unilateral bearing just allows charging handle to move electro-motor and gear.Gear assembly also can comprise axle that is connected to corresponding one of them gear and the one-way clutch that is connected to this.This one-way clutch can make in first gear, second gear and the 3rd gear each can only be along the operation of direction.
As on the other hand of the present utility model, a kind of electrical switchgear comprises: housing; Separable contacts; The operating mechanism that comprises the pivoted pole axis that is configured to the open and close separable contacts; And stored energy assembly, this stored energy assembly comprises: the mount pad that is connected to housing removedly; The stored energy mechanism that is connected to this mount pad and can between loading position and unloading position, moves; The gear assembly that comprises a plurality of gears; Can cooperate with gear so that the actuation element that stored energy mechanism is loaded, this actuation element can move in the primary importance of loading position with between corresponding to the second place of stored energy mechanism in unloading position corresponding to stored energy mechanism; Be connected to first load maintainer of corresponding one of them gear; And second load maintainer that is connected to corresponding one of them gear.Each equal carrier wheel in first load maintainer and second load maintainer is so that mobile actuation element and stored energy mechanism loaded.Stored energy mechanism, actuation element, gear assembly, first load maintainer and second load maintainer all are connected on the mount pad, thereby form sub-component, and this sub-component is connected on the housing of electrical switchgear removedly.
This electrical switchgear can be a circuit breaker.The housing of circuit breaker can comprise rear portion, front portion, first and second opposite side portions, top and from the rear portion outward extending bottom, thereby form chamber.The mount pad of stored energy assembly also can comprise the securing member of some, and the securing member of wherein said some can be fastening so that the sub-component of stored energy assembly is fastened on the rear portion of housing.When the mount pad with stored energy assembly is fastened on the rear portion of housing, sub-component can be arranged in the chamber, and in sub-component is arranged on chamber the time, can the place, front portion of the housing of circuit breaker or near near the front portion of mount pad.
Description of drawings
Description of preferred embodiments below reading in conjunction with the drawings can obtain to complete understanding of the present utility model, wherein:
Fig. 1 is according to the circuit breaker of an embodiment of the utility model and the exploded isometric chart of stored energy assembly thereof;
Fig. 2 is the circuit breaker of Fig. 1 and the isometric chart of stored energy assembly thereof, shows the stored energy assembly that is installed in Shell of circuit breaker inside;
Fig. 3 is the isometric chart of the stored energy assembly of Fig. 1;
Fig. 4 is the exploded isometric view of front portion of the stored energy assembly of Fig. 1;
Fig. 5 is the exploded isometric view at rear portion of the stored energy assembly of Fig. 4;
Fig. 6 is the isometric chart according to the charging handle that is used for stored energy assembly of an embodiment of the utility model;
Fig. 7 is the assembling isometric chart of the stored energy assembly of Fig. 4;
Fig. 8 A and 8B are respectively the end view and the front views of the stored energy assembly of Fig. 1, have wherein carried out revising being in closure and loading position so that this assembly to be shown;
Fig. 9 A, 9B and 9C are the end views of driven unit of the stored energy assembly of Fig. 1, and the parts that this assembly is shown respectively are in to be opened with unloading position, open and loading position and closure and loading position; And
Figure 10 A is the end view on the right side of stored energy assembly and time-delay mechanism thereof, shows this time-delay mechanism and is in and opens and unloading position; And
Figure 10 B, 10C and 10D are the end views of the time-delay mechanism of Figure 10 A, have wherein carried out revising so that this time-delay mechanism to be shown respectively being in and opening and loading position, closure and loading position and closure and unloading position.
Reference numerals list
2 electrical switchgears
4 housings
6 separable contacts
10 operating mechanisms
12 pole axis
The rear portion of 14 housings
The front portion of 15 housings
First sidepiece of 16 housings
Second sidepiece of 18 housings
The top of 20 housings
The bottom of 22 housings
24 chambers
30 securing members
40 linkage element
50 actuator arms
60 open spring
100 stored energy assemblies
102 mount pads
First sidepiece of 104 mount pads
Second sidepiece of 106 mount pads
The first end of 108 mount pads
The second end of 110 mount pads
The rear portion of 112 mount pads
The front portion of 114 mount pads
116 first side plates
118 second side plates
119 mounting blocks
120 springs
The first end of 122 springs
The second end of 124 springs
126 pitch of the laps
130 gear assemblies
132 first gears
134 second gears
136 the 3rd gears
The center of 138 the 3rd gears
The periphery of 140 the 3rd gears
The first of 142 first gears
The second portion of 144 first gears
The tooth of the first of 145 first gears
The tooth of the second portion of 146 first gears
The tooth of 147 second gears
The tooth of 148 the 3rd gears
150 actuation elements
152 planar sections
154 projections
156
158 one-way clutch
160 manual charging mechanism
162 charging handles
163 handles
164 unilateral bearings
165 cranks
166 first positioning indicators
The recess of 167 cranks
168 second positioning indicators
The axle of 169 cranks
170 autoloading structures
171 handle mount pads
172 electro-motors
The recess of 173 handle mount pads
174 gear boxes
180 sub-components
182 driven units
183 driving shafts
183 ' accessory
184 actuator arms
185 projections
186 actuators
186 ' actuator
187 projections
188 annexes
188 ' annex
188 " annex
190 installation components
The actuation element of 191 annexes
191 ' actuation element
192 first connectors
194 second connectors
196 wayss
198 lines of rabbet joint
200 locking parts
But the handle of 202 driven units changes projection
204 pivot members
206 cams
208 cam contours
210 roller assemblies
212 rollers
214 first toggle member
216 second toggle member
218 tripping operation lock bolts
220 torsion springs
222 backstops
The projection of 224 cams
300 time-delay mechanisms
302 first trip shaft
303 notch portion
304 second trip shaft
306 notch portion
308 elongate body
310 tripping operation flashboards
312 tripping operation flashboards
320 tie-in modules
322 first trip(ping) bars
324 second trip(ping) bars
326 tripping operation connecting pieces
340 tripping operation backstops
The first end of 342 tripping operation backstops
The second end of 344 tripping operation backstops
350 drive rods
352 first ends
354 the second ends
360 dampers
362 containers
364 air in certain amount
366 plungers
368 governor motions
369 connection connecting pieces
370 drive rod
372 drive the first end of rod
374 drive the second end of rod
380 biasing members
382 pitch of the laps
390 the 3rd trip shaft
392 tabs
394 notch portion
396 tabs
Embodiment
Illustrative purposes for example, embodiment of the present utility model will be described to be applied to medium voltage breaker, but clearly they also may be used on except medium voltage breaker and middle piezoelectricity air cock device various electrical switchgears (such as but not limited to, circuit switchgear and other circuit interrupter, contactor for example, motor starter, motor controller and other load controller).
The directivity term that uses in the literary composition, for example, top, bottom, upper and lower, forward and backward, clockwise, counterclockwise and their derivative, unless the clear and definite statement of Wen Zhongyou, otherwise all relate to the orientation of the element shown in the accompanying drawing, rather than the restriction claim.
As used herein, term " self-contained " refers to the modular nature of disclosed stored energy assembly, and the nearly all parts that wherein conventionally are connected to (for example " in be loaded on ") electrical switchgear independently are (such as but not limited to, closing spring; Auxiliary switch; Load motor; Charging handle) is co-located on the contrary on the independent removable sub-component.
As used herein, term " general " refers to that disclosed stored energy assembly is applied to the ability of various circuit breaker.
As used herein, term " actuator " and " actuation element " refer to be used for electrical switchgear (such as but not limited to, circuit switchgear, circuit breaker and other circuit interrupter, contactor for example, motor starter, motor controller and other load controller) any known or suitable output mechanism (such as but not limited to, trip actuator; Solenoid) and/or the element of this mechanism (such as but not limited to, arbor (stem); Plunger; Bar; Flashboard (paddle); Arm), described element moves so that handle other parts of electrical switchgear.
As used herein, " " any known or proper state that refers to electrical switchgear is (such as but not limited to, tripping operation for indicating device for term; Open; Closed) mark, it clearly includes but not limited to: visual detector for example is with the look indicating device, light-emitting diode (LED), the tripping operation flag, suitable word (for example " TRIPPED ") or suitable letter (for example " T ") or other suitable term or mark, and sound indicator for example the beep voice is transferred or other suitable sound.The utility model for example also can be imagined and to be word " ON " and " OFF " or just (+) and bear the mark of (-) symbol, and it indicates the non-tripped condition of electrical switchgear.
As used herein, term " linkage element " refers to be used for parts are connected to another any known or suitable mechanism, and it clearly includes but not limited to: rigid connection spare (such as but not limited to, arm; Pin; Rod), flexibly jointed chain spare (such as but not limited to, line; Chain; Rope), and elastic coupling spare (such as but not limited to, spring).
As used herein, term " securing member " refers to any suitable connection or retention mechanism, and it clearly includes but not limited to, screw, bolt, the combination of screw bolt and nut (such as but not limited to, locking nut) and bolt, packing ring and nut.
As used herein, " " statement together is meant that these parts directly join to together or engage by one or more intermediate members to two or more parts in connection.
As used herein, " quantity " is meant 1 or greater than 1 integer (that is, a plurality of) to term.
Fig. 1 and Fig. 2 show and are used for for example stored energy assembly 100 of medium voltage breaker 2 of electrical switchgear.Circuit breaker 2 comprises housing 4, separable contacts 6 (with dashed lines is illustrated in simplified form), and the operating mechanism 10 (illustrating in simplified form among Fig. 2) that is configured to open and close separable contacts 6 (Fig. 2).Exemplary operation mechanism 10 (Fig. 2) comprises the pivotable pole axis 12 that roughly extends between the opposite side portion 16,18 of Shell of circuit breaker 4.Except sidepiece 16,18, Shell of circuit breaker 4 also comprises rear portion 14, front portion 15, top 20 and bottom 22.Opposite side portion 16,18, top 20 and bottom 22 14 stretch out to form chamber 24 from the rear portion.Stored energy assembly 100 comprises mount pad 102, and it is configured to be connected to Shell of circuit breaker 4 removedly, thereby stored energy assembly 100 is set at the inside of chamber 24, as shown in Figure 2.
The mount pad 102 of example energy memory module 100 comprises first sidepiece 104, second sidepiece 106, first and second opposed ends 108,110, rear portion 112, and anterior 114, in the text shown in and in the example described this rear portion 112 be configured to be connected to the rear portion 14 of Shell of circuit breaker 4, when this front portion 114 is configured in stored energy assembly 100 is set at chamber 24, can be near this front portion 114, as shown in Figure 2 near 15 places, front portion of Shell of circuit breaker 4 or its.Exemplary mount pad 102 also comprises first and second side plates 116,118 and is arranged on a plurality of mounting blocks 119 between them.Stored energy mechanism for example spring 120 is connected to second side plate 118 at second sidepiece 106 of mount pad 102.Spring 120 can move between loading position (for example referring to Fig. 8 A and 8B) and unloading position (Fig. 1-5 and Fig. 7).Comprise that the gear assembly 130 of a plurality of gears 132,134,136 (at Fig. 3,4 and 5 in all illustrate) also is arranged on second sidepiece 106 of mount pad 102.
As shown in Figure 3, the gear 132,134,136 of gear assembly 130 can be operated with the primary importance that actuation element 150 is moved to Fig. 8 A and 8B (hereinafter discussing), thereby spring 120 is loaded.Actuation element 150 can also move to as the Fig. 1-5 and the second place shown in Figure 7, and its medi-spring 120 is arranged on unloading position.Stored energy assembly 100 also comprises first load maintainer 160 that is connected to gear 134, be connected to second load maintainer 170 of same gear 134, the utility model also can be applicable to be connected to any one this load maintainer in a plurality of gears 132,134,136 certainly.
More particularly, illustrate as Figure 4 and 5 the best, first and second load maintainers 160,170 of example energy memory module 100 all are configured to be connected to second gear 134.Therefore, first load maintainer 160 and second load maintainer 170 all move second gear 134, so that all gears 132,134,136 of carrier wheel assembly 130, thus mobile actuation element 150 and spring 120 loaded.In this respect, disclosed stored energy assembly 100 especially has advantage, because it only needs a gear assembly 130 to be used for the operation of first load maintainer and second load maintainer, wherein first load maintainer in the text shown in and in the example described for manual charging mechanism 160, the second load maintainers that comprise charging handle 162 in the text shown in and in the example described for comprising the autoloading structure 170 of electro-motor 170 and gear box 174.
The charging handle 162 of exemplary manual charging assembly 160 is connected to the handle mount pad 171 of the front portion 114 that is positioned at mount pad 102.More particularly, shown in Fig. 4 and 6, disclosed charging handle 162 comprises the handle 163 that is connected to crank 165 pivotly.Crank 165 is connected to handle mount pad 171 (Fig. 6) by axle 169 then.Axle 169 is connected to the unilateral bearing 164 of the aforesaid gear box 174 of operation (for simplicity of illustration, not shown internal gear), so that second gear 134 (Fig. 3-5) of swing pinion assembly 130 (Fig. 3-5).Therefore, gear box 174 and second gear 134 that is connected on it can come manual operation by the charging handle 162 of rotation (for example clockwise with respect to Fig. 6) manual charging mechanism 160, and operate automatically by the electro-motor 172 of autoloading structure 170.In other words, manual charging mechanism 160 is operated by the gear box 174 of autoloading structure 170, so that the gear 132,134,136 (Fig. 3-5) of carrier wheel assembly 130 (Fig. 3-5) and actuation element 150 (Fig. 3-5), thereby spring 120 is loaded (for example referring to Fig. 8 A and 8B be loaded spring 120).
This realizes by the unilateral bearing 164 that charging handle 162 is connected to pivotly gear box 174 to a great extent.This unilateral bearing is configured to: only when charging handle 167 when a predetermined direction (for example clockwise with respect to Fig. 6) rotates, just allow positive movement with steerage gear case 174.In other words, when charging handle 162 (for example counterclockwise with respect to Fig. 6) when rotation in opposite direction, unilateral bearing 164 interacts the forward between charging handle 162 and the gear box 174 to break away from.When electro-motor 172 operations, this unilateral bearing also makes charging handle 162 break away from.Therefore, although charging handle 162 and electro-motor 172 and being not used in operated simultaneously with swing pinion 134, each in them all can be operated separately with swing pinion 134.This of stored energy assembly 100 is to compare complete novelty and different designs with the design of known stored energy mechanism with the operation of automatically carrying out manually by same gear assembly 130, known stored energy mechanism usually uses independent and manual and automatic charging assembly independently, and each charging assembly has a plurality of separately, incoherent parts.
The uniqueness of disclosed manual charging mechanism 160 also is the setting of charging handle 162, and it is compact in design, still provides very big leverage effectively so that spring 120 is carried out manual loading simultaneously.Charging handle 162 also advantageously keeps being connected to stored energy assembly 100.More particularly, charging handle 162 is positioned at position shown in Figure 4 when not using, and wherein handle 163 is pivoted into by in the recess 167 of income crank 165.Crank 165 is then by in the recess 173 of income handle mount pad 171.When hope is carried out manual loading to spring 120, crank 164 and handle 163 can be opened to operable position, as shown in Figure 6.
Therefore, (for example Fig. 1-3) as shown in the figure, be to be understood that, spring 120, actuation element 150, gear assembly 130, first and second load maintainers 160,170, and time-delay mechanism 300 (will discuss with reference to figure 4,5,7,10A, 10B, 10C and 10D hereinafter) all is connected to mount pad 102, so that stored energy assembly 100 forms independent sub-component 180, it is configured to be connected to removedly Shell of circuit breaker 4, as shown in Figure 2.
More particularly, shown in Fig. 3-5 and 7 the bests, installation component 190 is configured to spring 120 is installed on second sidepiece 106 of mount pad 102, the first end 122 of its medi-spring 120 is positioned near the first end 108 of mount pad 102, and the second end 124 of spring 120 is towards the second end 110 extensions of mount pad 102.A plurality of pitch of the laps 126 extend between first and second ends 122 and 124 of spring 120.Exemplary installation component 190 comprises first connector 192, second connector 194 and ways 196, this first connector 192 first end 108 places of mount pad 102 or near stretch out from second sidepiece 106 of mount pad 102, this second connector 194 is connected to actuation element 150, and this ways 196 extends towards second connector 194 from first connector 192.Spring 120 is arranged between first connector 192 and second connector 194.Ways 196 extends through pitch of the laps 126.Therefore, when actuation element 150 was shifted to primary importance shown in Fig. 8 A and the 8B, second connector 194 was shifted to first connector 192, thereby spring 120 is loaded.On the contrary, when actuation element 150 was shifted to the second place of Fig. 3, second connector 194 moved away from first connector 192, thereby to spring 120 unloadings.
Example teeth wheel assembly 130 comprises three gears, promptly, be connected to first gear 132 of second sidepiece 106 of mount pad 102, be connected to aforesaid second gear 134 of the gear box 174 (Figure 4 and 5) of autoloading structure 170, and the 3rd gear 136 that is connected to actuation element 150 and cooperates with first and second gears 132 and 134.Therefore, as previously mentioned, manual charging mechanism 160 is connected to autoloading structure 170 (illustrating as Fig. 6 the best), and is configured to removable autoloading structure 170, so that move second gear 134.This is all gears 132,134,136 of carrier wheel assembly 130 then, and actuation element 150.Alternately, autoloading structure 170 can move second gear 134 independently.Exemplary the 3rd gear 136 comprises center 138 and overall periphery 140 for circle.Exemplary actuation element 150 has planar section 152 and projection 154, and this projection 154 vertically stretches out from planar section 152, shown in Fig. 3 and 4.Planar section 152 is connected to the 3rd gear 136, makes projection 154 between center 138 and overall periphery 140 for circle.Like this, when the 3rd gear 136 is pivoted and actuation element 150 when shifting to primary importance (Fig. 8 A and 8B), the projection 154 of actuation element 150 moves second connector 194 along first direction (for example making progress with respect to Fig. 3), spring 120 is compressed to the position shown in Fig. 8 A and Fig. 8 B.On the contrary, when the 3rd gear 136 is released (below discussion), the actuation element 150 that is connected to gear 136 is mobile rapidly (for example towards the second place of Fig. 3, pivot), thereby the projection of actuation element 150 154 moves second connector 194 along the second direction (for example downward with respect to Fig. 3) overall opposite with first direction, so that retracting spring 120.When spring 120 was released, the gear 132,134,136 of gear assembly 130 rotated freely, thereby allowed actuation element 150, especially projection 154 to move rapidly.Stored energy assembly 100, the especially operation of its driven unit 182 will be described in detail with reference to figure 9A, 9B and 9C hereinafter.
Continuation should be appreciated that with reference to figure 3 and Fig. 4 exemplary first gear 132 comprises first 142 and second portion 144.In the first 142 of first gear 132, the second portion of first gear 132 144, second gear 134 and the 3rd gear 136 each has a plurality of teeth 145,146,147,148 respectively.The tooth 147 of tooth 145 engagements second gear 134 of the first 142 of first gear 132.The tooth 148 of tooth 146 engagements the 3rd gear 136 of the second portion 144 of first gear 132.Therefore, when being moved for one in the gear 132,134,136 of gear assembly 130, all gears 132,134,136 all move, so that mobile as previously mentioned actuation element 150.
As shown in Figure 5, example teeth wheel assembly 130 also comprises and is connected to first gear 132 and from the outward extending axle 156 of first gear 132, and the one-way clutch 158 that is connected to axle 156.One-way clutch 158 is configured to only to allow in the gear 132,134,136 each to operate along a direction.Therefore, except other advantage, one-way clutch 158 also is used as release mechanism to prevent that spring 120 from being discharged unintentionally, and (being shown in broken lines with simple form among Fig. 5) pivots rapidly otherwise for example can cause charging handle 162, and may injure operator's (not shown).One-way clutch 158 also is used to allow spring 120 partly to be loaded.That is to say that spring 120 can be loaded into the degree of any hope between the complete loading position shown in unloading position for example shown in Figure 5 and Fig. 8 A, the 8B.
(also can referring to Fig. 1-5 and Fig. 7) shown in Fig. 8 A the best, the ways 196 of exemplary installation component 190 comprises the line of rabbet joint 198.The projection 154 of actuation element 150 (Fig. 3,4,7,8A and 8B)---its in the text shown in and described example in comprise the pin member---from the planar section 152 of actuation element 150 stretch out (as Fig. 3,4 and 8A shown in), and pass as previously discussed, the line of rabbet joint 198 of ways 196.Sell second connector 194 that member 154 uses any known or suitable fasteners defined in the literary compositions or retention mechanism to be connected to installation component 190 then.Therefore, the line of rabbet joint 198 can move the pin member 154 and second connector 194 with respect to ways 196, thereby spring 120 can be compressed to the loading position shown in Fig. 8 A and Fig. 8 B, perhaps is released to unloading position for example shown in Figure 3.
Therefore, should be appreciated that disclosed stored energy assembly 100 provides independently sub-component 180, it can use a plurality of securing members, such as but not limited to the screw 30 as shown in the example of Fig. 1, be connected to Shell of circuit breaker 4 relatively rapidly and easily removedly.More particularly, sub-component 180 comprises aforesaid mount pad 102, this mount pad 102 has first and second side plates 116 and 118, and all is connected to mount pad 102 and is configured to the manual charging mechanism 160 and the autoloading structure 170 of loading spring 120, and spring 120 also is connected to mount pad 102.Specifically, exemplary autoloading structure 170 comprises aforesaid electro-motor 170 and gear box 174, and wherein electro-motor 172 is positioned in fact on first sidepiece 104 of mount pad 102, and near first side plate, 116 places or its.Gear box 174 is between first side plate 116 and second side plate 118.
Such fact has also been discussed in the front: manual charging mechanism 160 and autoloading structure 170 are all operated same gear assembly 130 so that spring 120 is loaded (for example referring to Fig. 8 A and 8B be loaded spring 120).Gear assembly 130 can be cooperated with driven unit 182 (Fig. 1-5,8B, 9A-9C, 10A-10D) then, as will be discussed, this driven unit 182 is configured to mobile actuation element 150, projection 154 and second connector 194, so that the pole axis 12 (Fig. 1 and 2) of retracting spring 120 energy stored and running circuit breaker 2 (Fig. 1 and 2).Therefore, should be appreciated that disclosed stored energy assembly 100 comprises self-contained sub-component 180.The quantity that it is also understood that the parts that usually need with stored energy mechanism is compared, and the design of this self-contained sub-component 180 has significantly reduced the quantity of parts.For example (but being not limited to), according to an embodiment of the present utility model, with the stored energy assembly of known medium voltage breaker (not shown) needed usually 300 or more multi-part quantity compare, whole number of components of stored energy assembly 100 reduce to about 100 parts.The self-contained character of disclosed just stored energy assembly 100 makes this become possibility.
In addition, by a kind of independently self-contained sub-component 180 is provided, disclosed stored energy assembly 100 as a kind of can be than the current mechanism that faster and easily is applicable to various application scenarios and/or various circuit breakers.Specifically, be fixed on mount pad 102 in the chamber 24 of Shell of circuit breaker 4, as shown in Figure 2, sub-component 180 can be connected to Shell of circuit breaker 4 fast and easily sub-component 180 by trip bolt 30 (Fig. 1).For example, thus compare with known medium voltage breaker design (not shown)---the independent parts of wherein one or more stored energy assemblies usually in be contained in the Shell of circuit breaker need dismantle circuit breaker at least in part---modularized design also make stored energy assembly 100 assembling, maintenance, replacing and/or safeguard than faster and easily.It should also be understood that, as will be hereinafter described in greater detail, additional parts, such as but not limited to positioning indicator 166,168 (for example referring to Fig. 1-4 first positioning indicator 166 and second positioning indicator 168), actuator (for example referring to Fig. 1-5,7,8B and 10A first and second buttons 186,186 '), and annex is (for example referring to Fig. 1,2,4,5,7 and the annex 188 of 10A, Fig. 1-5,7 annex 188 ', the annex 188 of Fig. 4,5,10A ") also can be connected to the mount pad 102 of disclosed stored energy assembly 100.Exemplary mount pad 102 comprises first positioning indicator 166, and it can move between the second place (Fig. 8 B) of primary importance (Fig. 1-4) of indicating separable contacts 6 (Fig. 2) to open and indication separable contacts 6 (Fig. 2) closure.Second positioning indicator 168 moves between first (Fig. 3) and second (clearly not illustrating) position so that indicate spring 120 unloaded (Fig. 3) respectively and load the state of (clearly do not illustrate, still can referring to Fig. 4).But should be appreciated that positioning indicator, actuator and/or the annex that can use any known or suitable optional quantity, type and/or configuration, and can not depart from scope of the present utility model.
Below with reference to Fig. 9 A-9C 182 pairs of springs 120 of driven unit (Fig. 1-5,7) being discussed loads and unloads, and the pole axis 12 (Fig. 1 and 2) of running circuit breaker operating mechanism 10 (illustrating in simplified form among Fig. 2), so that the operation of open and close separable contacts 6 (being shown in broken lines in simplified form among Fig. 2).Specifically, Fig. 9 A-9C shows second side plate 118 of the mount pad 102 of stored energy assembly 100, and be arranged on driven unit 182 and autoloading structure 170 between first and second side plates (, in Fig. 9 A-9C, having removed first side plate 116) for simplicity of illustration.Driven unit 182 shown in Fig. 9 A is positioned to be opened and unloading position, and Fig. 9 B illustrates and opens and loading position, and Fig. 9 C illustrates closed and loading position (also can be positioned at closure and unloading position referring to dashed line view cam 206 being shown among Fig. 9 C) with real diagram.Each figure among Fig. 9 A-9C also shows the end-view of aforesaid one-way clutch 158 and the 3rd trip shaft 390 (hereinafter will describe).
Exemplary driver assembly 182 comprises the driving shaft 183 that is connected in pivotly between first side plate 116 and second side plate 118 (the two is all shown in Fig. 1-5,7, the 8B), and from driving shaft 183 outward extending arms 184.Arm 184 is configured to be connected to the pole axis 12 (Fig. 1 and 2) of circuit breaker operation mechanism 10 (illustrating in simplified form among Fig. 2), especially be connected to from pole axis 12 outward extending actuator arms 50, as shown in Figure 2 by suitable linkage element 40 (among Fig. 2 in simplified form dashed line view illustrate).Therefore, driven unit 182 is configured to from the storage power of the spring 120 (Fig. 1-5,7,8A, 8B) of energy memory module 100 (for example, when spring 120 when the loading position of Fig. 8 A and Fig. 8 B is released) be converted into the motion of the pole axis 12 (Fig. 1 and 2) of circuit breaker operation mechanism 10 (Fig. 2) so that the separable contacts 6 (being shown in broken lines in simplified form among Fig. 2) of close circuit breaker 2 (Fig. 1 and 2) as required.Should be appreciated that retracting spring 120 energy stored for example also be used for to some open spring 60 (referring to, such as but not limited to, the single spring 60 of opening shown in Fig. 2) load.Therefore, should be appreciated that driven unit 182 is also removable to open separable contacts 6 (Fig. 2), will discuss to this below.
Be connected to first toggle member 214 of roller assembly 210 pivotly away from a part, shown in Fig. 9 A-9C with the arm 184 of the tie point of linkage element 40 (Fig. 2).Except first toggle member 214, but example roller assembly 210 also comprises the roller 212 on the profile 208 that is configured to be biased in pivot cam 206, be connected to second toggle member 216 of first toggle member 214 pivotly, and between the reset position shown in the trip position shown in Fig. 9 A and Fig. 9 B, the 9C biased tripping operation lock bolt 218.Specifically, cam 206 can corresponding to the primary importance shown in Fig. 9 A of the spring 120 (Fig. 1-5,7,8A and 8B) unloaded (Fig. 1-5,7) of stored energy assembly 100 (also can referring to the cam that is in primary importance 206 that is shown in phantom line among Fig. 9 C) and be loaded Fig. 9 B of (Fig. 8 A and 8B) corresponding to spring 120 (Fig. 1-5,7,8A and 8B) and the second place shown in the 9C (illustrating with real diagram among Fig. 9 C) between move.Tripping operation lock bolt 218 is connected to second toggle member 216 pivotly, therefore can operate second toggle member 216, roller 212 and first toggle member 214 with slide roller assembly 210, thereby move and (for example, pivot counterclockwise with respect to Fig. 9 A and 9B around driving shaft 183; Pivot clockwise with respect to Fig. 9 C) arm 184 of driven unit 182.Biased element, such as but not limited to shown in torsion spring 220, towards reset position (Fig. 9 B, 9C) bias voltage tripping operation lock bolt 218.
Driven unit 182 also comprises first trip shaft 302 (hereinafter will go through) and the 3rd trip shaft 390, this first trip shaft 302 comprises that notch portion (cut-out portion) 303, the three trip shaft 390 that are configured to allow tripping operation lock bolt 218 to break away from (Fig. 9 A) with first trip shaft 302 respectively and engage (Fig. 9 B, 9C) comprise and is configured to the notch portion 394 of the backstop 222 of engages drive assembly 182 releasedly.For the separable contacts 6 (Fig. 2) of close circuit breaker (Fig. 1 and 2), the 3rd trip shaft 390 can manually or automatically be pivoted, and discharges the backstop 222 of driven unit 182 up to notch portion 394.This discharges then from cam 206 outward extending projections 224, thus release cam 206, and this cam 206 discharges the spring 120 (Fig. 1-5,7,8A and 8B) that connects thereon.In response, cam 206 when the spring 120 that has been discharged (Fig. 1-5,7,8A, 8B) energy stored drives, pivot (for example, counterclockwise) with respect to Fig. 9 A-9C.Therefore, the periphery 208 of cam 206 is cooperated with the roller 212 of roller assembly 210, actuating arm 184 is moved to the make position of Fig. 9 C.
For example, in order to operate driven unit 182 to open the separable contacts 6 (Fig. 2) of circuit breaker 2 (Fig. 1 and 2), first trip shaft 302 manually or automatically (is hereinafter discussed) to pivot, to discharge tripping operation lock bolt 218.In response, roller assembly 210, the roller 212 of the periphery 208 of engagement cam 206 is moved especially movably, thereby cam 206 can be moved.Therefore, discharging tripping operation lock bolt 218 moves the second toggle connecting piece 216, the second toggle connecting piece, 216 slide rollers 212, thus translating cam 206 and the first toggle connecting piece, 214, the first toggle connecting pieces, 214 driving arms 184 are to open separable contacts 6 (Fig. 2).Open spring (such as but not limited to, Fig. 2 open spring 60) by bias voltage pole axis 12 (Fig. 1 and 2) thus bias voltage is connected to this motion that the actuating arm 184 of pole axis 12 (Fig. 1 and 2) has promoted driven unit 182.
As Fig. 4,5,7 and 10A-10D shown in, stored energy assembly 100 also can comprise time-delay mechanism 300.Time-delay mechanism 300 is configured to provide the delay from the very first time to second time, in the described very first time, first trip shaft 302 begins to move from primary importance, and in described second time, second trip shaft 304 (hereinafter describing) is moved to discharge tripping operation backstop 340 (hereinafter describing).Like this, can between the time that separable contacts 6 (Fig. 2) tripping operation of initial time of taking place of for example electric fault situation and circuit breaker 2 (Fig. 1 and 2) is opened, obtain corresponding the delay.Disclosed time-delay mechanism 300 can also regulate, and (for example, shortens thereby can control as required; Prolong) this delay.
Time-delay mechanism 300 comprises first trip shaft 302 and second trip shaft 304, this first trip shaft 302 is connected between the side plate 116 and 118 of mount pad 102 pivotly, and first sidepiece 104 at mount pad 102 extends through first side plate 116, as shown in Figure 7, similarly, this second trip shaft 304 is connected to mount pad 102 pivotly near first trip shaft 302.Discuss in conjunction with Fig. 9 A-9C as the front, first trip shaft 302 can be cooperated with driven unit 182, and can be loaded the primary importance (Figure 10 B and 10C) of (Fig. 8 A and 8B) at the spring 120 (Fig. 1-5,7,8A and 8B) corresponding to stored energy assembly 100 and corresponding to moving between the second place (Figure 10 A and 10D) of spring 120 (Fig. 1-5,7,8A and 8B) unloaded (Fig. 1-5 and 7).
As Fig. 4,5 and 10C shown in, second trip shaft 304 of time-delay mechanism 300 comprises notch portion 306, it is similar to the above-mentioned notch portion 303 (Fig. 5,7,9A, 9B and 9C) of first trip shaft 302.The tie-in module 320 of time-delay mechanism 300 has a plurality of linkage element 322,324,326 with 302,304 interconnection of first and second trip shaft, so that one motion in first trip shaft 302 and second trip shaft 304 causes another motion in first trip shaft 302 and second trip shaft 304.Aforesaid tripping operation backstop 340 comprises the first end 342 that is connected to first trip shaft 302, and the second end 344 that can engage with second trip shaft 304.Therefore, tripping operation backstop 340 can move with first trip shaft 302, but can not be with respect to first trip shaft, 302 independent moving.Exemplary time-delay mechanism 300 also comprises drive rod 350, and it has the first end 352 that is connected to first trip shaft 302 and is oppositely arranged with first end 352 and away from the second end 354 of first end 352.Damper 360 is connected to drive rod 350.Damper 360 is adjustable, so that adjust the delay of time-delay mechanism 300, hereinafter will discuss this.
When first trip shaft 302 from primary importance (for example, loading) (Figure 10 B and 10C) (for example shifts to the second place, unloading) when (Figure 10 A and 10D), first trip shaft 302 moves the linkage element 322,324,326 of tie-in module 320, thereby pivots second trip shaft 304.When second trip shaft 304 was pivoted, the notch portion 306 of second trip shaft 304 (the best illustrates among Figure 10 C) discharged tripping operation backstop 340, thus allow tripping operation backstop 340 and and then first trip shaft 302 move to the second place of Figure 10 A and 10D.When first trip shaft 302 moves to the described second place, tripping operation lock bolt (Fig. 9 A-9C) is released, so that allow to open pole axis 12 (Fig. 1 and 2), actuator arm 50 (Fig. 2) and the linkage element 40 (being shown in phantom line among Fig. 2) of spring (for example referring to Fig. 2 open spring 60) running circuit breaker (Fig. 1 and 2).This mobile then driven unit 182 and permission separable contacts (Fig. 2) are opened, as previously described.
The linkage element of exemplary tie-in module 320 comprises from first trip shaft, 302 outward extending first trip(ping) bars 322, stretch out and totally be parallel to second trip(ping) bar 324 of first trip(ping) bar 322 from second trip shaft 304, and the tripping operation connecting piece 326 that makes 322,324 interconnection of first and second trip(ping) bars, as shown in the figure.The linkage element 322,324,326 of tie-in module 320 and the damper 360 of time-delay mechanism 300 all help aforesaid delay.This example damper is an air buffer 360, it comprises the container 362 with air in certain amount 364 (with dashed lines illustrates in simplified form among Fig. 4), from container 362 outward extending plungers 366 (the best illustrates the Figure 4 and 5), and the governor motion 368 (Fig. 3,4,10A, 10B, 10C and 10D) that is used to regulate the amount of the air 364 (Fig. 4) in the container 362.The governor motion 368 of example damper 360 is securing members, such as but not limited to, screw or bolt, this securing member is adjustable (for example, being tightened) along first direction, so that reduce the amount of the air 364 (Fig. 4) in the container 362, thereby reduce the delay of stored energy assembly 100, and this securing member is adjustable (for example, released) along second direction, so that increase the amount of the air 364 (Fig. 4) in the container 362, thereby increase described delay.Damper 360 comprises also and connecting with connecting piece 369 that its plunger 366 with damper 360 is connected to the drive rod 350 of time-delay mechanism 300, shown in Fig. 5 and 7.
In the example that illustrates in the text and describe, time-delay mechanism 300 is arranged on first sidepiece 104 of stored energy assembly 100 basically.The driving shaft 183 of aforesaid driven unit 182 (for example referring to Fig. 7) also on first sidepiece of stored energy assembly 100 mount pad 102 from stored energy assembly 100 stretch out.Exemplary driver axle 183 comprises accessory (attachment) 183 ', and this accessory 183 ' has at least one projection, such as but not limited to, the relative projection 185,187 that in Fig. 4,5 and 7, all illustrates.Connector 370 is---excellent for driving in its example that illustrates in the text and describe---, and comprise the first end 372 that is connected to gudgeon (trunnion) 189 movably and extends through gudgeon 189, this gudgeon 189 is positioned between the relative projection 185,187 of driving shaft accessory 183 '.The second end 374 that drives rod 370 is at the second end 354 places of drive rod 350 or be connected to the drive rod 350 of time-delay mechanism 300 near it.Biasing member, such as but not limited to Fig. 4,5,7 and 10A-10D shown in spring 380, be positioned between the gudgeon 189 and drive rod 350 of driving shaft accessory 183 '.Specifically, exemplary spring 380 comprises a plurality of pitch of the laps 382, drives rod 370 and extends through these pitch of the laps 382.Therefore, spring 380 bias voltage drive rods 350 are away from driving shaft 183, thereby towards the second place (Figure 10 A and 10D) bias voltage first trip shaft 302, so that keep the forward between the parts (such as but not limited to, linkage element 322,324,326) of first trip shaft 302 and time-delay mechanism 300 to engage.
Therefore, should be appreciated that disclosed time-delay mechanism 300 is connected to the mount pad 102 of stored energy assembly 100, thereby form the part of aforesaid independent sub-component 180 (for example referring to Figure 10 A), this sub-component 180 is connected to Shell of circuit breaker 4 removedly, as illustrated in fig. 1 and 2.
For activated drive assembly 182, example energy memory module 100 comprises at least one actuator 186,186 ', 188,188 ', 188 " (all shown in Figure 7).Specifically, example energy memory module 100 comprises at least one manual actuator, such as but not limited to, first (for example ON) button 186 and second (for example OFF) button 186 ', described button all can extend from front portion 114 manual activation of stored energy assembly 100 and towards the rear portion 112 of stored energy assembly 100, so that can cooperate with corresponding trip shaft (for example referring to, first button 186 and pivot member 204 thereof, they can be cooperated with the tab 392 of the 3rd trip shaft 390 among mobile Fig. 5 and the 10A; Also can be referring to extending towards the rear portion 112 of mount pad 102 so that second button 186 ' of cooperating with the tripping operation flashboard 310 of first trip shaft 302 among Fig. 5 and the 10C) (can also referring to the Fig. 1-3 and the 8B of the front portion that first and second buttons 186 and 186 ' are shown), also comprise at least one annex 188 (Fig. 1,2,4,5,7,10A-10D), 188 ' (Fig. 1-5,7), 188 " (Fig. 2,4,5,7 and 10A), described annex operable automatically is to move corresponding trip shaft (for example 302,390).For example, shown in Figure 10 A-10D, example energy memory module 100 comprises the shunt trip 188 of some.Each shunt trip 188 has corresponding actuation element, such as but not limited to, the arbor 191 that illustrates, this arbor 191 are configured to for example to engage in response to detecting the electric fault situation and move the corresponding tripping operation flashboard 312 on the body 308 that is arranged on first trip shaft 302.Another annex 188 " also comprise arbor 191 ', this arbor 191 ' is actuatable engaging and to move tab 396 of the 3rd trip shaft 390, so that the separable contacts 6 (Fig. 2) of close circuit breaker 2 (Fig. 1 and 2) automatically of position for example from afar.
First (for example ON) pivot member 204 of button 186 is connected to the end of first button 186 pivotly, shown in Figure 10 A.Locking part 200 is connected to first sidepiece 104 of the mount pad 102 of stored energy assembly 100 movably, and can between the primary importance (illustrating with solid line among Figure 10 A) and the second place (being shown in phantom line among Figure 10 A), move, described primary importance can be moved by the movable link 204 of first button 186 corresponding to the tab 392 of the 3rd trip shaft 390, and the described second place can not move by the actuating of first button 186 corresponding to the tab 392 of the 3rd trip shaft 390.Specifically, when locking part 200 was arranged in the second place that Figure 10 A is shown in phantom line, this locking part moved to the corresponding position that also is shown in phantom line with the pivot member 204 of first button 186 in Figure 10 A.But locking part 200 and pivot member 204 (are partly illustrated with imaginary line in Figure 10 A by the pivot projections 202 of driving shaft accessory 183 '; Also can be referring to Figure 10 C and 10D) move to these positions.Specifically, when driving shaft 183 and accessory 183 ' thereof are moved to corresponding to the closed position (Figure 10 C and 10D) of the separable contacts 6 (Fig. 2) of circuit breaker 2 (Fig. 1 and 2),, pivot projections 202 arrives the position that is shown in phantom line among Figure 10 A but engaging and move (for example with respect to Figure 10 A upwards) locking part 200.Therefore, locking part 200 prevents that first button 186 from activateding, thereby it is unloaded so that mobile driven unit 182 and close circuit breaker separable contacts 6 (Fig. 2) afterwards, do not conform to the desirably situation of retracting spring 120 (Fig. 1-5,7,8A and 8B) at spring 120.
Therefore, should be appreciated that disclosed time-delay mechanism 300 provides lot of advantages.Wherein, scalable is exactly an aspect, thus control lag in the operation of stored energy assembly 100 as required.It also comprises the parts of lesser amt and is mechanical in nature, thereby reliable and manufacturing cost is lower.In addition, time-delay mechanism 300 is connected on the mount pad 102 of stored energy assembly 100 fully, thereby has kept the favourable self-contained modularized design of stored energy assembly 100.Like this, stored energy assembly 100 can be than faster and easily being applicable to various application, and various different electrical switchgear (such as but not limited to, medium voltage breaker).
Though described specific embodiment of the utility model in detail, it will be appreciated by those skilled in the art that according to comprehensive instruction of the present utility model and can carry out various modification and change to these details.Therefore, disclosed specific setting only is to illustrate for example, rather than limits scope of the present utility model, and scope of the present utility model provides by claims and any and full contents all equivalents thereof.
Claims (20)
1. stored energy assembly (100) that is used to comprise the electrical switchgear (2) of housing (4) is characterized in that described stored energy assembly (100) comprising:
Be configured to be connected to removedly the mount pad (102) of described housing (4);
The stored energy mechanism (120) that is connected to described mount pad (102) and can between loading position and unloading position, moves;
The gear assembly (130) that comprises a plurality of gears (132,134,136);
Can cooperate with described gear (132,134,136) so that the actuation element (150) that described stored energy mechanism (120) is loaded, described actuation element (150) can move in the primary importance that is positioned at described loading position corresponding to described stored energy mechanism (120) with between corresponding to the second place of described stored energy mechanism (120) in described unloading position;
Be connected to first load maintainer (160) of the corresponding gear (134) in the described gear (132,134,136); And
Be connected to second load maintainer (170) of the described corresponding gear (134) in the described gear (132,134,136),
Wherein, each in described first load maintainer (160) and described second load maintainer (170) is configured to move described gear (132,134,136), so that move described actuation element (150) and described stored energy mechanism (120) loaded, and
Wherein, described stored energy mechanism (120), described actuation element (150), described gear assembly (130), described first load maintainer (160) and described second load maintainer (170) are connected to described mount pad (102), thereby form sub-component (180), this sub-component (180) is configured to be connected to removedly the described housing (4) of described electrical switchgear (2).
2. stored energy assembly according to claim 1 (100), it is characterized in that, described mount pad (102) comprises first sidepiece (104), second sidepiece (106), first end (108), be oppositely arranged with described first end (108) and away from the second end (110) of described first end (108), being configured to be connected to the rear portion (112) of described housing (4) and being configured to can be from the outside approaching front portion (114) of described housing (4); Described stored energy mechanism comprises spring (120) and is configured to described spring (120) is installed in installation component (190) on second sidepiece (106) of described mount pad (102); A plurality of pitch of the laps (126) of the second end (124) that described spring (120) has near the first end (108) that is positioned at described mount pad (102) first end (122), extend towards the second end (110) of described mount pad (102) and extension between the second end (124) of the first end (122) of described spring (120) and described spring (120).
3. stored energy assembly according to claim 2 (100), it is characterized in that the first end (108) that described installation component (190) is included in described mount pad (102) locates or near outward extending first connector of second sidepiece (106) (192) from described mount pad (102), the ways (196) that is connected to second connector (194) of described actuation element (150) and extends between described first connector (192) and described second connector (194); Described spring (120) is positioned between described first connector (192) and described second connector (194); Described ways (196) extends through described pitch of the laps (126); When described actuation element (150) when shifting to described primary importance, described second connector (194) is configured to shift to described first connector (192), so that described spring (120) is loaded; And when described actuation element (150) when shifting to the described second place, described second connector (194) is configured to move away from described first connector (192), so that described spring (120) is unloaded.
4. stored energy assembly according to claim 3 (100) is characterized in that, described first load maintainer is to operate so that the manual charging mechanism (160) that described spring (120) is loaded by hand; Described second load maintainer is can operate so that to the automatic autoloading structure (170) that loads of described spring (120); Described gear comprises first gear (132) of second sidepiece (106) that is connected to described mount pad (102), the 3rd gear (136) that is connected to second gear (134) of described autoloading structure (170) and is connected to described actuation element (150) and can cooperates with described first gear (132) and described second gear (134); Described manual charging mechanism (160) is connected to described autoloading structure (170), and is configured to move described autoloading structure (170) so that move described second gear (134).
5. stored energy assembly according to claim 4 (100) is characterized in that, described the 3rd gear (136) comprises center (138) and overall periphery (140) for circle; Described actuation element (150) comprise planar section (152) with from the vertical outward extending projection of described planar section (152) (154); Described planar section (152) is connected to described the 3rd gear (136), and wherein said projection (154) is positioned at described center (138) and described overall between the circular periphery (140); When described the 3rd gear (136) is pivoted and described actuation element (150) when shifting to described primary importance, the described projection (154) of described actuation element (150) moves described second connector (194) so that compress described spring (120) along first direction; And, when described the 3rd gear (136) is pivoted and described actuation element (150) when shifting to the described second place, the described projection (154) of described actuation element (150) moves described second connector (194) along opposite with described first direction generally second direction, so that discharge described spring (120).
6. stored energy assembly according to claim 4 (100) is characterized in that, described first gear (132) comprises first (142) and second portion (144); In the described first (142) of described first gear (132), the described second portion (144) of described first gear (132), described second gear (134) and described the 3rd gear (136) each has a plurality of teeth (145,146,147,148); The described tooth (147) of described tooth (145) described second gear of engagement (134) of the described first (142) of described first gear (132); The described tooth (148) of described tooth (146) described the 3rd gear of engagement (136) of the described second portion (144) of described first gear (132); And when being moved for one in the described gear (132,134,136) of described gear assembly (130), all described gears (132,134,136) move so that move described actuation element (150).
7. stored energy assembly according to claim 4 (100) is characterized in that, described manual charging mechanism (160) comprises charging handle (162) and unilateral bearing (164); Described autoloading structure (170) comprises electro-motor (172); Described unilateral bearing (164) is positioned between described charging handle (162) and the described electro-motor (172); Have only when described charging handle (162) when a predetermined direction moves, described unilateral bearing (164) just allows described charging handle (162) to move described electro-motor (172) and described second gear (134); Described gear assembly (130) also comprises the one-way clutch (158) that is connected to corresponding one axle (156) in the described gear (132,134,136) and is connected to described axle (156); And described one-way clutch (158) only allows in described first gear (132), described second gear (134) and described the 3rd gear (136) each to operate along a direction.
8. stored energy assembly according to claim 3 (100) is characterized in that, described ways (196) comprises the line of rabbet joint (198); Described actuation element (150) comprises corresponding one (136) the outward extending pin members (154) from the described gear of described gear assembly (130); And described pin member (154) extends through the described line of rabbet joint (198) and is connected to described second connector (194), so that described pin member (154) and described second connector (194) can move with respect to described ways (196).
9. stored energy assembly according to claim 2 (100), it is characterized in that described mount pad (102) also comprises first side plate (116), and second side plate (118) that is oppositely arranged of described first side plate (116), the mounting blocks (119) that is positioned at the some between described first side plate (116) and described second side plate (118); Described first load maintainer is the manual charging mechanism (160) that comprises charging handle (162); Described charging handle (162) is connected to the described front portion (114) of described mount pad (102) pivotly between described first side plate (116) and described second side plate (118).
10. stored energy assembly according to claim 9 (100) is characterized in that, described second load maintainer is the autoloading structure (170) that comprises electro-motor (172) and gear box (174); First sidepiece (104) that described electro-motor (172) is positioned at described mount pad (102) substantially go up and described first side plate (116) locate or near; Described gear box (174) is positioned between described first side plate (116) and described second side plate (118).
11. an electrical switchgear (2) is characterized in that comprising:
Housing (4);
Separable contacts (6);
Operating mechanism (10), this operating mechanism (10) comprise the pivotable pole axis (12) that is configured to the described separable contacts of open and close (6); And
Stored energy assembly (100), this stored energy assembly (100) comprising:
Be connected to the mount pad (102) of described housing (4) removedly;
The stored energy mechanism (120) that is connected to described mount pad (102) and can between loading position and unloading position, moves;
The gear assembly (130) that comprises a plurality of gears (132,134,136);
Can cooperate with described gear (132,134,136) so that the actuation element (150) that described stored energy mechanism (120) is loaded, described actuation element (150) can move between the primary importance and the second place, described primary importance is positioned at described loading position corresponding to described stored energy mechanism (120), and the described second place is positioned at described unloading position corresponding to described stored energy mechanism (120);
Be connected to first load maintainer (160) of corresponding (134) in the described gear (132,134,136); And
Be connected to second load maintainer (170) of described corresponding (134) in the described gear (132,134,136),
Wherein, each in described first load maintainer (160) and described second load maintainer (170) moves described gear (132,134,136), so that move described actuation element (150) and described stored energy mechanism (120) loaded, and
Wherein, described stored energy mechanism (120), described actuation element (150), described gear assembly (130), described first load maintainer (160) and described second load maintainer (170) are connected to described mount pad (102), thereby form sub-component (180), this sub-component (180) is connected on the described housing (4) of described electrical switchgear (2) removedly.
12. electrical switchgear according to claim 11 (2), it is characterized in that the described mount pad (102) of described stored energy assembly (100) comprises first sidepiece (104), second sidepiece (106), first end (108), be oppositely arranged with described first end (108) and away from the second end (110), rear portion (112) and anterior (114) of described first end (108); The described stored energy mechanism (120) of described stored energy assembly (100) comprises spring (120) and installation component (190); A plurality of pitch of the laps (126) of the second end (124) that described spring (120) has near the first end (108) that is positioned at described mount pad (102) first end (122), extend towards the second end (110) of described mount pad (102) and extension between the second end (124) of the first end (122) of described spring (120) and described spring (120); The first end (108) that described installation component (190) is included in described mount pad (102) locates or near outward extending first connector of second sidepiece (106) (192) from described mount pad (102), the ways (196) that is connected to second connector (194) of described actuation element (150) and extends between described first connector (192) and described second connector (194); Described spring (120) is positioned between described first connector (192) and described second connector (194); Described ways (196) extends through the described pitch of the laps (126) of described spring (120); When described actuation element (150) when shifting to described primary importance, described second connector (194) is shifted to described first connector (192), so that described spring (120) is loaded; And when described actuation element (150) when shifting to the described second place, described second connector (194) moves away from described first connector (192), so that described spring (120) is unloaded.
13. electrical switchgear according to claim 12 (2), it is characterized in that described first load maintainer (160) of described stored energy assembly (100) is to operate so that the manual charging mechanism (160) that described spring (120) is loaded by hand; Described second load maintainer (170) of described stored energy assembly (100) is can operate so that to the automatic autoloading structure (170) that loads of described spring (120); The described gear (132,134,136) of the described gear assembly (130) of described stored energy assembly (100) comprise second sidepiece (106) that is connected to described mount pad (102) first gear (132), be connected to second gear (134) of described autoloading structure (170) and described manual charging mechanism (160) and comprise center (138) and overall the 3rd gear (136) for circular periphery (140); Described the 3rd gear (136) can be cooperated with described first gear (132) and described second gear (134); Described actuation element (150) comprise planar section (152) with from the vertical outward extending projection of described planar section (152) (154); Described planar section (152) is connected to described the 3rd gear (136), and wherein said projection (154) is positioned at described center (138) and described overall between the circular periphery (140); When described the 3rd gear (136) is pivoted and described actuation element (150) when shifting to described primary importance, described actuation element (150) moves described second connector (194) so that compress described spring (120) along first direction; And, when described the 3rd gear (136) is pivoted and described actuation element (150) when shifting to the described second place, described actuation element (150) moves described second connector (194) along opposite with described first direction generally second direction, so that discharge described spring (120).
14. electrical switchgear according to claim 13 (2) is characterized in that, described first gear (132) comprises first (142) and second portion (144); In the described first (142) of described first gear (132), the described second portion (144) of described first gear (132), described second gear (134) and described the 3rd gear (136) each has a plurality of teeth (145,146,147,148); The described tooth (147) of described tooth (145) described second gear of engagement (134) of the described first (142) of described first gear (132); The described tooth (148) of described tooth (146) described the 3rd gear of engagement (136) of the described second portion (144) of described first gear (132); And when being moved for one in the described gear (132,134,136) of described gear assembly (130), all described gears (132,134,136) of described gear assembly (130) move so that move described actuation element (150).
15. electrical switchgear according to claim 13 (2) is characterized in that, the described manual charging mechanism (160) of described stored energy assembly (100) comprises charging handle (162) and unilateral bearing (164); Described autoloading structure (170) comprises electro-motor (172); Described unilateral bearing (164) is positioned between described charging handle (162) and the described electro-motor (172); Have only when described charging handle (162) when a predetermined direction moves, described unilateral bearing (164) just allows described charging handle (162) to move described electro-motor (172) and described second gear (134); Described gear assembly (130) also comprises corresponding one axle (156) that is connected in the described gear (132,134,136); Described one-way clutch (158) only allows in described first gear (132), described second gear (134) and described the 3rd gear (136) each to operate along a direction.
16. electrical switchgear according to claim 12 (2), it is characterized in that the described mount pad (102) of described stored energy assembly (100) also comprises first side plate (116), and second side plate (118) that is oppositely arranged of described first side plate (116), the mounting blocks (119) that is positioned at the some between described first side plate (116) and described second side plate (118); Described first load maintainer (160) of described stored energy assembly (100) is the manual charging mechanism (160) that comprises charging handle (162); Described charging handle (162) is connected to the described front portion (114) of described mount pad (102) pivotly between described first side plate (116) and described second side plate (118); Described second load maintainer is the autoloading structure (170) that comprises electro-motor (172) and gear box (174); First sidepiece (104) that described electro-motor (172) is located substantially on described mount pad (102) go up and described first side plate (116) locate or near; Described gear box (174) is positioned between described first side plate (116) and described second side plate (118).
17. electrical switchgear according to claim 16 (2), it is characterized in that, described stored energy assembly (100) also comprises driven unit (182), this driven unit (182) be included between described first side plate (116) and described second side plate (118) extend and be positioned near the second end (110) of described mount pad (102) driving shaft (183) and from the outward extending actuator arm of described driving shaft (183) (184); Described actuator arm (184) is connected to the described pole axis (12) of the described operating mechanism (10) of described electrical switchgear (2); And described driving shaft (183) can be cooperated with the described actuation element (150) and the described gear assembly (130) of described stored energy assembly (100), and is configured to move described pole axis (12).
18. electrical switchgear according to claim 11 (2) is characterized in that, described stored energy assembly (100) also comprises at least one manual actuator (186) and at least one annex (188); In described at least one manual actuator (186) and described at least one annex (188) each can activated, so that activate the described stored energy mechanism (120) of described stored energy assembly (100).
19. electrical switchgear according to claim 18 (2) is characterized in that, described stored energy assembly (100) also comprises first positioning indicator (166) and second positioning indicator (168); Described first positioning indicator (166) is connected to described at least one actuator (186); Move between the closed second place of the described separable contacts (6) that described first positioning indicator (166) can described therein first positioning indicator (166) indicates primary importance that the described separable contacts (6) of described electrical switchgear (2) opens and wherein said first positioning indicator (166) to indicate described electrical switchgear (2); Described second positioning indicator (168) can be cooperated with described actuation element (150); Move between the unloaded second place of the described stored energy mechanism (120) that described second positioning indicator (168) can described therein second positioning indicator (168) indicates primary importance that the described stored energy mechanism (120) of described stored energy assembly (100) is loaded and wherein said second positioning indicator (168) to indicate described stored energy assembly (100).
20. electrical switchgear according to claim 11 (2) is characterized in that, described electrical switchgear is circuit breaker (2); The described housing (4) of described circuit breaker comprises rear portion (14), anterior (15), first and second opposite side portions (16,18), top (20) and from outward extending bottom, described rear portion (14) (22), thereby forms chamber (24); The described mount pad (102) of described stored energy assembly (100) also comprises the securing member (30) of some; The securing member of described some (30) can fastenedly be fastened on the described rear portion (14) of described housing (4) with the described sub-component (180) with described stored energy assembly (100); When the described mount pad (102) of described stored energy assembly (100) was secured to the described rear portion (14) of described housing (4), described sub-component (180) was set in the described chamber (24); In the time of in described sub-component (180) is set at described chamber (24), can the described front portion (15) of the described housing (4) of described circuit breaker (2) locate or near near the described front portion (114) of described mount pad (102).
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CNU2008201798682U CN201323138Y (en) | 2008-07-03 | 2008-07-03 | Electrical switching device and energy storage component thereof |
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CNU2008201798682U CN201323138Y (en) | 2008-07-03 | 2008-07-03 | Electrical switching device and energy storage component thereof |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101425405B (en) * | 2007-06-01 | 2013-09-11 | 伊顿公司 | Electrical switching apparatus and stored energy assembly therefor |
CN106463285A (en) * | 2014-04-03 | 2017-02-22 | 伊顿公司 | Electrical switching apparatus and dampening assembly therefor |
-
2008
- 2008-07-03 CN CNU2008201798682U patent/CN201323138Y/en not_active Expired - Fee Related
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101425405B (en) * | 2007-06-01 | 2013-09-11 | 伊顿公司 | Electrical switching apparatus and stored energy assembly therefor |
CN106463285A (en) * | 2014-04-03 | 2017-02-22 | 伊顿公司 | Electrical switching apparatus and dampening assembly therefor |
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