DE1301387B - Mercury delay switch - Google Patents

Description

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The invention relates to a mercury-restricted passage for the non-conductive medium Delay switch with a housing, consisting of a mastery of the switching operations in one of two chambers, which allow a wide area between them and with great accuracy. and float amount of mercury as well as a light.

contain non-conductive flowable medium and 5 A particularly simple construction is after a achieved by a main line for transferring the embodiment of the invention in that Mercury, a shunt line for transferring the separating body itself in a manner known per se tion only of the non-conductive medium and is porous. That way you don't need any additional another, a limited permeability separating path with an additional porous component schafkörper containing way for the non-conductive ίο fen, it will rather be the main and Medium connected, with the input to the bypass line in which the required Shunt line is provided from the separating body providing permeability to the amount of mercury, one of the two switch positions is initially blocked

will. Contacts arranged in the first chamber. Even

In a known switch of this type, the 15 is hereby the simplicity of construction and the promoted three parallel ways to transfer the mercury switching function.

Silver and the non-conductive medium and to the After another embodiment of the invention

delay of this medium in the case of a ring-shaped manure, the separating body is a non-metallic one Housing made of three structurally separate branches of the disc, each with an opening as the main or used pipe system. This gives 20 shunt lines plus one for the non-conductive one that the known switch popped up considerable dimensions medium limited permeable breakthrough has and above all sensitive and thus has.

is prone to failure. As a result of the branched pipe system According to a further embodiment of the invention

makes the mastery of the respective differences make the contacts in a known manner between the individual switching times of the two 35 the form of metallic plates and are at each Shifting difficulties. attached to an axial end face of the separating body.

There is also a mercury delay switch.This also makes a very simple and easy-to-use, in which the housing enables the shape of a cylindrical compact design.

thresh, closed at its axial ends, According to another embodiment of the invention

through the radial separating body in two chambers 30, the chambers are each divided by circular arcs Has tube. In these known mige grooves in each axial end face of the non-ME switches however, only a metallic disk is formed in the separating body. This results in a two openings provided, one of which has a very small design and one only permeable to a limited extent for the non-conductive measurement, which is particularly favorable for the switching process dium is. These known separators are related to mercury. But it can also be one of the Kamnis-like expensive, since on the one hand a special cone can be formed by a groove that defines the axial design of the breakthrough for the mercury to connect end faces of the non-metallic disc, This also leads to a very simple construction of the delay element in the breakthrough for the non-conductive switch with very small dimensions, tending medium must be used. Even with the 40 The invention and its advantages are in the sen known switches can be the difference of the following detailed description of several off-switching times between the two switching operations management examples in conjunction with the drawing explained only inadequately and in a narrow area. In the drawing shows there will be reigns. F i g. 1 a time characteristic to explain the

The invention is based on the object of achieving a 45 sought effect of the invention, Mercury delay switch of the F i g. 2, 3 and 4 sectional views of a first

to create given type, which is a simple and possible management form of a manufactured according to the invention lent insensitive construction with lower mercury delay switch in the positions has measurements and at the same time an »off« or »on« or »off«, as extensive and precise mastery as possible of the 50 F i g. 5 to 12 different views of a second Differences in the switching times between the two embodiments of a switch element, namely Switching operations is enabled. This is shown in FIG. 5 and 7 views facing each other-

Invention achieved in that the housing in at the ends of the in

known way the shape of a cylindrical, F i g. 6 washer shown in section after Ab-

closed at its axial ends, by which the metal end contacts in the switch radial separating body would "excee" divided into two chambers,

res has, and that the separating body the main Fig. 8 and 10 views opposite one another

line, the shunt line and a limited gender end of the in

contains permeable part. Thereby the advantage F i g. 9 disk shown in section, according to Aberzielt, that the main line, the shunt line 60 would take the metal end contacts after the and the way with the limited permeability isolating switch element into its "on" position moves the workbody are formed in the separator itself,

and thereby additional conduction paths or even Fig. 11 and 12 views opposite one another.

Pipelines are dispensable. Through the trailing ends of the pane after removing the metal assembly of the conduction paths in the separator 65 have end contacts immediately after the discharge a very short design of the switch allows switching movement of the switch element, light. As a result of the compact arrangement with very Fig. 13 to 20 different views of a third

short conduction paths and a well-defined th embodiment of a switch element, namely

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Figures 13 and 15 are views of mercury 20 from chamber 17 into the chamber, facing each other

lying ends of the in 18 when the closing movement of the

Fig. 14 shown in section disk after Ab housing takes place. The rest, not from the mercury would take the metal end contacts in the switch 20 and the part 16 occupied interior of the

position »off«, 5 tube 11 is pressurized by a

16 and 18 are views of one another, non-conductive flowable medium, e.g. B. water lying ends of the fabric filled.

F i g. 17 in section shown disc, after Ab- The inner diameter of the tube 11 forms a

would take the metal end contacts, in the main switch shunt, and part 16 forms one

setting »on«, OK delay device in this main line. Of the

19 and 20 are views of one another - part 16 is also provided with a longitudinal direction

lying ends of the disc, as provided directly fenden cylindrical opening 21, the

after the switch element has switched off, the chambers 17 and 18 freely connect to one another,

ments would appear. When the switch-on movement of the housing 11

From the time characteristic representation in FIG. 1 is followed by 15, the housing from the in F i g. 2 dargestellzu can be seen that the switch, if, as left below th position in the in F i g. 3 is the position shown on the time characteristic that moves one of the contacts away. The non-conductive switch element located in the chamber 18 is bridged, switched on, the flowable medium is displaced and detached by the flowing in of the mercury 20 in this chamber and the housing is in its "on" position. When the switch-off movement takes place, the 20 is moved through the line 21 directly into the housing chamber into its "off" position. The contact 17 and thus enables almost instantaneous overclocks to remain, however, during a time chamber 18 labeled δ following the execution of the mercury from chamber 17 in the switching movement. As a result, the bridging takes place permanently. If a closing movement of the contacts 14 and 15 then takes place almost simultaneously with the movement of the housing, its position becomes the closing movement.

"Off" is changed to "on", and the contacts are then bridged when the immediate switch-off movement. The next switch-off movement takes place, blocking that now in the chamber 18 of the housing would normally contain a time-contained mercury span δ after this switch-off movement, the break-out in chamber 18, as shown in FIG. 4 shows, and the order of contacts follows. How, however, F i g. 1 shows that 30 bars 14 and 15 remain bridged. Small mercury causes a silver plug occurring within the time span δ then to flow to the extent that the switch-on movement that bridges the contacts in the chamber 17 contains non-conductive flow. Even if the next switch-off-capable medium slowly flows through the flowable part 16 into the chamber 18 immediately after the previous switch-on media, the switch 35 described here has collapsed through the main line 19. After one of element no memory of the previous training of the density of the material of the part 16, its Vbschaltbewegung, with the result that the contacts lumen, etc. dependent period of time decreases the mercury during one of the last switch-off of the silver mirror in the chamber 18 below with the inlet of the housing span δ bridged lead- - Breakthrough 21 in chamber 18 and so this ben. In other words, the shortest possible, a 40 free entry. At this moment there is a switch-off movement of the housing following the direct connection between the chambers 17 and tion is equal to δ, or in other words, the 18, and the rest of the mercury in the chamber 18 is able to switch every time an off - flows immediately through the main line 19 in the cam-switching movement of the housing takes place, the delay 17 and thus causes the delay time δ to be produced at this moment, namely without back-45 the contacts 14 and 15 are no longer bridged, see when - with respect to the switch-on movement - both entries of the opening 21 are so small movement - this switch-off movement takes place. that they do not allow mercury to enter the

F i g. 2 shows the first embodiment of the break permit. Like F i g. 2, 3 and 4 show, the switch element 10, which has a housing in the form of an entry of the opening 21 into chamber 17 never through cylindrical glass tube 11, which blocks the mercury 20 at its so, no matter in which front axial end 12 the housing is by a stalk position. The entry of the penetration and at its rear axial end through a breakthrough 21 in chamber 18, however, can be closed off by the base 13, in which a pair of contacts 14 and 15 are blocked by mercury, but only after they have been melted. Between the tender switch-off movement of the housing to its “off” position shown in the fused-shut axial ends 12 and 13 of the tube. As a result of this res 11 is an arrangement that is permeable to flowable media, the part 16 has the effect of arranging the porous part 16, which connects the interior of the raw material of the non-conductive flowable medium 11 into an “off” chamber 17 at the axial end 12 see the chambers being sized and thus dividing the flow and an "one" chamber 18 at the axial end 13. control of mercury. It should be noted that the flowable media permeable part 16 is 60 this arrangement, the switch element 10 in the einaus gefrittetem material, the z. B. described by a sin- gangs and in the time diagram of the terurigs method to a for a flowable measurement. 1 can be effective,
dium permeable mass is formed. In FIGS. 5 to 12, a second embodiment - the part 16 is provided with an axially extending main form of the invention as a switch element 30 - is shown which is close to a cylindrical 65. It has a housing in the form of a non-wall of the tube 11. Between the chambers conductive disc 31 made of ceramic material 17 and 18, the main line 19 forms a connection od. The like. Between a pair of metal plates, which is wide enough to allow the flow of the 32 and 33, which in this embodiment the Con-

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form bars, is fitted. Figures 5, 6 and 7 show 30 operating in the same way as the embodiment Housing in the "off" position, and Fig. 5 and 7 approximately form 10, so in the time diagram of the show opposing axial end faces F i g. 1 illustrated way.

of the disc when the housing is in this position. Another embodiment of the invention

is located. The 5 located near the metal disk 32 in FIGS. 13 to 20 shown. The switch element axial end face of the disc 31 has an approximately 50 in its kind that already described switch element 30 similar to about half the circumference of the disc, i. i.e., it consists of one Ring groove 34 on. The close to the metal disk 33 housing in the form of a non-conductive disk 51, the The axial end face of the disk 31 is formed with a groove35 between a pair of metal contacts 52 and 53 which fits about a quarter of the umio. In this embodiment, however, The beginning of the disk goes around and the annular groove 34 only the “off” chamber through a segmented groove 54 slightly overlapped. Where the grooves 34 and 35 are in the end face of the close to the contact 53 overlap others, connects an axially extending washer 51 and the "a" chamber through a segdie Main shunt line forming breakthrough mented breakthrough 55 formed by one 36 the two grooves. Firmly in the opening 36 one 15 end face of the disc 51 goes through to the other and a flowable media is fitted so that the two contacts 52 and 53 are connected. At Material 37, the flow rate of the non-conductive one end of each of the chambers 54 and 55 near the flowable medium between the two grooves each end faces of the disc is a groove 34 and 35 dimensioned when the position of the housing is provided from a shallower depth in such a way that will be changed. The non-overlapping ends 20 have these grooves of shallower depth in each end face of the grooves 34 and 35 are overlapped by a main line. The skin shunt 56 38 connected, which connects the two parts of shallower depth and to transfer the mercury silver 39 between the grooves 34 and 35 is used. The contains the delay device 57 in the form of a The remainder of the part formed by the grooves 34 and 35 that is permeable to flowable media. the mes, which is not ingested by the mercury, 25 main line 58 connects the chambers 54 and 55 is with a pressurized non-conductive at adjacent ends and is used for overflow Medium, e.g. B. hydrogen filled. be of mercury 60 between the chambers. When the switch element connects in the circuit shown in FIGS. 5, 6, the secondary shunt 59 connects and 7 is the position shown, the contacts are also the chambers 54 and 55, like the characters-32, 33 is not bridged by the mercury 39, since 30 shows voltage. The rest of the through chambers 54 and all the mercury in the space formed "from" chamber 34, not that of the mercury is melted. If the switch-on movement of the housing is taken, a pressurized one has taken place, it is turned "in" into its position and set a non-conductive flowable medium, the then approximately horizontal main line 38 z. B. hydrogen filled.

lets the mercury 39 contained in the groove 34 into 35. When the switch element 50 is in the in the groove 35 run, as shown in FIGS. 8 and 10. The "off" position shown in Figs. 13, 14 and 15 befin mercury flow speaks at about the same time as the end, all the mercury in the "off" chamber 54 is switching movement of the housing on as a result of the pre-included. The rotation of the switch element 50 in presence of the secondary bypass line 40, its "on" position causes that in the chamber which connects the groove 34 directly to the groove 35 and allows 40 54 contained mercury partially through the main, that the line 58 flows out of the groove 35 through the inflow into the chamber 55 and so the Kondes Mercury displaced flowable medium clocks 52 and 53 bridged, since the chamber 55 at flows directly into the groove 34. In this position, each axial end faces the contacts 52 and 53 contacts 32 and 33 through that in groove 34 which is open. The flow of mercury through the Groove 35 and the mercury 45 main line 58 contained in the main line 38 occur essentially simultaneously bridged silver. with the switch-on movement of the housing because the

When the housing is in its secondary bypass line 59 in Figs. 11 and 12, the chambers 54 The position shown "off" is moved, causes the and 55 to connect directly and thus enables initial switch-off movement of the housing that contained in the chamber 55 and through the one Lumps of mercury in the groove 35 displaced the inlet 50 flowing mercury from this chamber the secondary bypass line 40 to the groove 35 immediately closes the flowable medium into the chamber 54. This prevents a quick return. This state of the switch element is in tion of the mercury from the groove 35 into the groove 34, Fig. 16, 17 and 18 shown, because when the mercury moves from the groove the contacts 52 and 53 are separated when

to the groove 34 the 55 enclosed in the groove 34 the mercury from the "a" chamber 55 into the Flowable medium only flows back through the "out" chamber 54. The emptying of the Delay device 37 entering groove 35 takes place after rotation of the housing in chamber 55 can. Gradually enough fluid medium becomes "off" its position. The switch-off movement of the displaced, and the mirror of the housing in the groove 35 initially causes that in the Kamhandenen Mercury sinks below a point, at 60 mer55 contained mercury the entrance of the that of the entry of the secondary bypass line 59 into the chamber is revealed to the groove 35, whereby the grooves 55 blocked. As a result, the mercury can and 35 are freely connected to one another again. In not quickly from the chamber 55 through the main of this Moment the rest of the mercury line 58 flows into the chamber 54 because of the flow in the groove 35 suddenly through the main line 38 in 65 chamber 54 displaced hydrogen by the Verdie Groove 34, as the drawing shows, and the delay device 57 must go through it in order to get into cycles are no longer bridged. From the above to get to the chamber 55. As a result, this works Description it follows that the embodiment contained in the chamber 55 mercury only long-

sam through the main line 58 until the level of the mercury remaining in the chamber 55 drops below the entrance of the secondary bypass 59 to chamber 55. At this moment the chambers 54 and 55 are connected to one another by the open shunt line 59, and the mercury still remaining in the chamber 55 is quickly transferred into the chamber 54 and thereby separates the contacts 52 and 53.

Also in this embodiment it can be seen that the closing movement of the housing at any moment before the mercury entered the input the line 59 to the chamber 55 reveals the part of the mercury contained in the chamber 54 immediately can flow back into the chamber 55. This puts the mercury in the chamber 55 back in immediately the same state it was in when the housing was moved to the "on" position the previous time became. In other words, the switch element 50 shows no indication of its "off" and "off" position thus operates in the same way as in the timing diagram of FIG. 1 shown.

Although, as shown in the drawing and described above, a single main shunt is capable of almost the transfer of mercury from the "out" chamber to the "in" chamber to carry out simultaneously with the switch-on movement of the housing, it goes without saying that several lines could functionally achieve the same result as a single main shunt. It should also be noted that in each of the embodiments, there is a delayed response to the The switch-on movement can be built in by inserting a mass that is permeable to flowable media the main shunt. This arrangement would allow a switch design that both delayed switch-on as well as delayed switch-off permitted.

Claims (7)

Claims: 40 1. Mercury delay switch with a housing consisting of two chambers, one Amount of mercury floating between them as well as a non-conductive flowable Contain medium and the through a main line for the transfer of the mercury, a Shunt line for transferring only the non-conductive medium as well as another, a path for the non-conductive medium containing a limited permeability separating body are connected, the input to the bypass line from the amount of mercury in the one of the two switching positions is initially blocked, characterized in that that the housing in a manner known per se has the shape of a cylindrical, at its axial ends has a closed tube divided into two chambers by the radial separating body, and that the separator restricts the main line, the shunt line and one contains permeable part. 2. Switch according to claim 1, characterized in that the separating body (16) is itself porous in a manner known per se. 3. Switch according to claim 1 or 2, characterized in that the contacts (14, 15) in on are arranged in a known manner in the first chamber (18). 4. Switch according to claim 1, characterized in that the separating body is a non-metallic Disc (31, 51, 60) is each one breakthrough as a main or shunt line as well as a breakthrough which is permeable to a limited extent for the non-conductive medium. 5. Switch according to one or more of claims 1, 2 and 4, characterized in that the contacts in a manner known per se are in the form of metallic plates (32, 33; 52, 53) and each have an axial end face of the separating body ( 31, 51) are attached. 6. Switch according to one of claims 4 and 5, characterized in that the chambers each by circular arc-shaped grooves (34, 35) in each axial end face of the non-metallic Disc are formed. 7. Switch according to claim 6, characterized in that one of the chambers is through a groove (55) connecting the axial end faces of the non-metallic disc (51). 1 sheet of drawings 909534/110