DE1295210B - Measuring device for monitoring the energy consumption - Google Patents

Description

The invention relates to a measuring device for monitoring the energy consumption a measuring interval divided into two time intervals, in particular for monitoring the day and night consumption of energy. Such a measuring device is particularly suitable for tariffs that are made dependent on the condition that larger quantities at night must be obtained than during the day.

It is a maximum electricity meter with periodically reset returning driver and resettable maximum indicator known, each measuring interval being subdivided into a plurality of equal time intervals. With such a maximum counter, the present invention is based Task, the energy consumption of a measurement interval divided into two time intervals to monitor, not to solve.

It is also a device for determining average stress curves known for electrical systems, with a series of counters that alternately, for example, from hour to hour, via clutches that can be engaged and disengaged is operated by a counter. The details of the individual counters correspond the average loads at the relevant time of day. Such a device could indeed be divided into two time intervals to monitor the energy consumption Measuring intervals are used, but the evaluation of the measurement results is difficult, because the two counters are not automatically reset after a measuring interval. Furthermore, a display device for a double maximum counter is known, wherein a driver indicating the current consumption value is provided, which is optionally by means of a switching device known per se with one of two towed Pointers can be coupled. With this known device, the energy supply can can be monitored in two time intervals, but the energy consumption is from both time intervals to be compared only as a single value and not also as a total value readable. In addition, only maximum values can be compared with one another, since the Drag pointers cannot be automatically reset after a measuring interval.

Finally, a measuring device for monitoring the energy consumption is one in two time intervals subdivided measurement interval became known, in which two independent counting elements via alternately engageable clutches from a receiving device are moved one after the other in such a way that the energy consumption can be read as a single value in both time intervals to be compared, with as Counting organs with concentrically arranged scales used cooperating pointers are. Here, in one time interval, one pointer is clockwise and in the other time interval the other pointer moves in the opposite direction of rotation. Immediately before the start of a new measuring interval, the first pointer to be moved returned to its original position. Apart from the fact that the evaluation of the If you only have problems with measured values for a short time, you can take a reading of the total value is not possible.

Eventually, various other devices have come to be known, such as a Double tariff index, in which a switchover from one index to another Counter is made with the help of a swivel axis or swivel bracket. At a known maximum measuring apparatus act on this at the same time two counters in Aron circuit in such a way that a scale and a pointer are adjusted in opposite directions, so that the total value can be read off. In a known display device for a Total remote measuring system, with several pointers that can move against each other, these are operated one after the other in such a way that when the first Measured value all pointers and each additional measured value when transmitting one less pointer can be taken along by the measured value receiver. Also is an apparatus for displaying mean values became known, with also several drivers are provided that work with the same registration periods, but with different ones Times can be returned to the zero position. All of these devices are for surveillance of the energy consumption of a measurement interval divided into two time intervals suitable.

Furthermore, the so-called maximum watchdogs have also become known at which a pointer with constant angular velocity and a pointer with an angular velocity is driven in the same direction according to the electrical power. Also such Devices are not suitable for monitoring energy consumption.

The present invention relates to a measuring device for monitoring the energy consumption of a measurement interval divided into two time intervals, in particular for monitoring the day and night consumption of energy, in which two of each other independent counting organs via alternately engageable clutches from a counter either directly or indirectly via adjustable gears and amplifier motors are moved one after the other in such a way that the energy consumption in both can be compared Time intervals can be read off as a single value, with concentric counting elements arranged scales cooperating pointers are used. The invention lies the underlying task here is to create a measuring device that significantly improves the evaluation facilitated, with the energy consumption of both to be compared on the basis of scales Time intervals can be read off both as a single value and as a total value. this is achieved according to the invention in that the pointer with the couplings over such trained drive members are connected that in the first time interval of non-driven pointer automatically follows the driven pointer, in the second Time interval but only the following pointer is driven and that after each Measuring interval the two pointers automatically into theirs after disengaging the clutches Starting position to be postponed.

With reference to the drawing, in which several exemplary embodiments, in particular Scale arrangements are shown schematically, the invention is explained in more detail.

F i g. 1 a shows an exemplary embodiment of a measuring device for monitoring the day and night consumption of energy, with only those for understanding the invention required parts are shown.

F i g. 1 b shows a circuit example of the device. 1 with a pointer is referred to, which is used to display the day reference according to the selected application example. The corresponding pointer for the night reference is denoted by 2. The pointer 1 is attached to an axle 3 serving as a drive element, which is drivingly connected via a driver arm 4 to a driver 5 on a driver plate 6 designed as a toothed wheel, a toothed wheel 7 and a clutch pinion 8 with a drive shaft 9. The axis 9 is preferably driven by a motor M 1 of a receiving device I, which is connected in a manner known per se to an adjusting gear (not shown in the drawing). The drive plate 6 sits loosely on the axis 3 and is under the action of a spring-loaded return rake 10, which turns the drive plate 6 clockwise when the drive is disengaged so that a stop 11 attached to the plate 6 comes to rest against a fixed locking cam 12 .

A ratchet wheel 13, which cooperates with a locking lever 15 pivotable about an axis 14, is also attached to the axis 3. The end 16 of the locking lever is actuated directly or indirectly by a relay R 1 (FIG. 1 b) for unlocking, as will be explained in more detail below. If the locking of the wheel 13 is released by lifting the locking lever 15 , the axle 3 with the pointer 1 is returned to the starting position under the action of a further spring-loaded reset rake 17. This is determined by the position of the pin 5 on which the driver arm 4 rests.

The pointer 2 is mounted on a hollow shaft 18 serving as a drive element, which is in drive connection via a gear 19, a gear 20, a clutch pinion 21 and an axle 22 with a motor M 2 of a receiving device 1I, which is connected to the same setting gear. But it can also be connected to a setting gear of its own counter.

The hollow shaft 18 or the gear 19 is under the action of a spring-loaded reset rake 23, which seeks to adjust the hollow shaft 18 with disk 19 and pointer 2 counterclockwise. However, an adjustment can only occur when the drive for the night time reference is disconnected by lifting the pinion 21 and the locking of a locking wheel 24 seated on the hollow shaft 18 is canceled by lifting a locking lever 25. In this case, the disk 19 is adjusted counterclockwise until a stop 26 attached to the disk 19 comes to rest on a locking arm 27 which is non-rotatably attached to the axis 3. The lever 25 can be rotated about an axis 28 and is actuated directly or indirectly by a further relay R 2 (FIG. 1 b). This is always the case when night reference is switched off and day reference is switched on.

F i g. 1 b shows an embodiment of the circuit. The pulses coming from the setting gear of the counter via a line L are received by the receiving devices I and II. In a known manner, these consist of an amplifier motor M 1 or M 2 and a receiving relay R 11 or R 21. The motors M 1 and M 2 are always connected to voltage. Both receiving relays R 11 and R 21 are connected in parallel so that they are actuated simultaneously by the incoming pulses. Depending on whether day or night consumption is to be displayed, contacts t and n of a time switch Sch actuate tariff relays R 12 and R 22. The tariff relay R 12 (day) lets the clutch 7, 8 (Fig. 1 a) come into engagement when it is attracted and releases it when it is de-energized, which occurs when the time switch is switched from day to night tariff happens. At the same time the tariff relay R 22 (night) is energized and allows the clutch 20, 21 ( FIG. 1) to engage.

With h is a manual key with which the two locking relays R 1 and R 2 assigned to the locking levers 15 and 25 can be energized so that they disengage the locking levers from their ratchet wheels. The locking relay R 2 is assigned a release relay R 3, which holds it mechanically in the disengaged position. The trip relay receives voltage via contact n of the timer when switching from day to night tariff, picks up and releases the blocking relay R 2. W denotes series resistors.

In Fig. 2 three different pointer positions are illustrated. The pointers 1 and 2 cooperate with disc or circular ring-shaped scales 29, 30 . The scale 29 is numbered counterclockwise from the center, while the numbering of the scale 30 begins at the end number of the scale 29 and is plotted in a clockwise direction. Since, according to the agreement, the day reference may only amount to 50% of the maximum reference in the chosen embodiment, the scale 29 assigned to the day reference is only numbered from 0 to 50%, while the night reference can be larger and therefore the scale 30, for example, from 0 to 100 % is numbered. F i g. 2 a shows the pointer position of the two pointers 1 and 2 at the beginning of the measuring period.

In this position, the pointer 2 for the night reference is completely covered by the pointer 1 for the day reference. According to FIG. 1, the stop 11 rests against the locking cam 12, the arm 4 rests against the driver 5 and the stop pin 26 rests against the locking arm 27. The relay R 2 is attracted and releases the lock 24, 25. The relay R 12 is also attracted and couples the wheels 7 and B. The incoming pulses actuate the relay R 11, which controls the motor M 1. The axis 3 and thus the pointer 1 for the daytime consumption are now driven counter-clockwise via the wheels 7 and 6 and the drivers 5, 4. Since the pinion 21 is decoupled and the lock at 24, 25 is released, the pointer 2 constantly follows the position of the pointer 1 under the action of the spring-loaded reset rake 23. The stop pin 26 always rests on the lever 27.

When switching from Tagbezug at night reference at the end of the first part of the measurement period that the lock 24, 25 associated with relay R 2 is brought by energization of the relay R3 to fall through the switch Sch. The locking lever 25 thereby engages with the locking wheel 24. At the same time, the day reference is uncoupled at 8 (relay R 12 drops out) and the night reference is switched on by coupling the wheels 20 and 21 (relay R 22 picks up). While the pointer 1 for the day reference in the FIG. 2 b end position shown remains (lock 13, 15 is not canceled) now the pointer 2 moves clockwise. After disconnecting the day reference at 8 , the stop disk 6 returns to the starting position under the action of the spring-loaded reset rake 10 , while the position of the pointer 1 is retained by the lock 13, 15. At the end of the second part of the measuring period (Fig. 3 c) the night time reference is disconnected at 21 by the timer Sch (relay R 22 drops out) and the day reference is engaged at 8 (relay R 12 picks up), so that the counting of the day reference begins again. Since the arm 4 has not changed its position, but only the pin 5 on the disk 6 has been returned to the starting position, only the disk 6 is initially rotated when the day reference is fed in.

From Fig. 2 c it is easy to see how big the day and the night cover were. If pointer 2 would be in the middle of the scale when switching to the daily tariff have stopped, i.e. at the starting point of the 24-hour measurement period, then would be the night consumption has been equal to the day consumption. Since the pointer 2 but over this Point, the consumption has been greater during the night than during of the day.

In the selected embodiment, the pointer reset is carried out manually by the operations manager. To do this, he has to press the h key. As a result, the relays assigned to the locking levers 15 and 25 are connected to voltage, so that the locking wheels 13 and 24 are released. Then the pointers 1 and 2 return under the action of the spring-loaded reset rakes 17 and 23 in their starting position or in the day position assumed in the meantime. This position is given by the contact between pin 4 and pin 5 . If the pointer is not reset immediately after switching from night to day reference, but later, the disk 6 has already rotated further through a corresponding angle, so that the zero position can then no longer be reached. After the operations manager has pressed a key, the pointers jump back into cover, namely to the point on the scale that corresponds to the level of consumption taken from the beginning of the measuring period up to this point in time.

The in F i g. The scale arrangement shown in FIG. 2 has only a purely optical one Meaning. The numbering is exactly correct in the event that 50 per cent day and 50 per cent Night consumption. A reading as a percentage of the total consumption is so only given then. In contrast, the determination of the same day and night applies to every consumption correct.

F i g. Figure 3 shows a different dial arrangement that gives better reading of the consumption in percent (of course only from the one on the setting gear preselected reference quantity). The scale 29 for the day reference is the same as in the embodiment according to FIG. 2. In contrast to before is the scale 30 for the night reference with the pointer 1 firmly connected, so that they are so with this moved to the left by the daily consumption. In this way it is achieved that at the beginning of the night consumption the pointer 2 for the night reference always at the beginning the scale for the night reference is. F i g. 3 a shows the position of the pointer 1 and 2 and the position of the scales 29 and 30 at the beginning of the measuring period, F i g. 3 b at Switching from day to night reference and F i g. 3 c at the end of the measurement period. The pointers show the actual consumption as a percentage of the preselected at the end of the measuring period Amount, if this was really purchased. If the reference amount is smaller than the preselected, the percentage is of course proportional to the amount actually purchased.

In Fig. 4 shows a further scale arrangement, wherein F i g. 4 a the pointer and scale position at the beginning of the measuring period, F i g. 4 b at Switching from day to night reference and F i g. 4 c illustrate at the end of the measurement period. In this embodiment, the start of the measurement period is at the left point on the scale. The pointers 1 and 2 are again in cover. The starting position of the pointer is not in the middle, but at the left end of the scale. Pointer 1 is now based on the daily consumption Moved clockwise and the pointer 2 follows the pointer in the usual way 1. When switching to the night tariff, pointer 1 and the pointer remain stationary 2 continues to rotate in the same direction of rotation until the end of the measuring period night consumption is switched off. Since the scale for night consumption is the same as for Embodiment according to FIG. 3 is connected to the pointer 1, can be this way you can read off the daytime consumption as well as the nighttime consumption separately. In addition, this version offers the possibility that at the end of the measuring period it can be determined whether the preselected quantity has been reached or not. whether it was exceeded. The sum of the readings as a percentage on both scales gives the percentage of the preselected amount. The embodiment according to F i G. 4 can be derived in a simple manner from the in FIG. 1 developed example.

Claims (6)

Claims: 1. Measuring device for monitoring the energy consumption of a measuring interval divided into two time intervals, in particular for monitoring the day and night consumption of energy, with two independent counting organs either directly or via alternately engageable clutches from a meter indirectly moved in such a way one after the other via adjustable gears and amplifier motors that the energy consumption in both time intervals to be compared as a single value can be read, cooperating as counting organs with concentrically arranged scales Pointers are used, d a - characterized in that the pointers (1, 2) with the Couplings (8, 21) are connected via drive elements (3, 18) designed in this way, that in the first time interval the non-driven pointer (2) to the driven Pointer (1) follows automatically, but only the one that follows in the second time interval Pointer (2) is driven, and that after each measuring interval the two pointers (1, 2) automatically returned to its original position after disengaging the clutches (8, 21) will. 2. Measuring device according to claim 1, characterized by on the drive elements (3,18) attached ratchet wheels, which interact with locking levers (15, 25) by which fixes the position of the pointer (1, 2) in the respective switching positions is, and by spring-loaded return rake (17, 23), through which when released the locking lever (15, 25) the pointers (1, 2) jump back to their starting position. 3. Measuring device according to claim 1 and 2, characterized by a spring-loaded reset rake, under the action of which the one pointer (2) carrying the drive member (18) is in such a way that the pointer (2) is always the position of the pointer (1) when the lock is released follows. 4. Measuring device according to claim 1 to 3, characterized by a on the axis (3) rotatably arranged disc (6) which is under the action of a spring-loaded reset rake (10) , via which the drive of the drive member (3) for the pointer ( 1) takes place indirectly. 5. Measuring device according to one of claims 1 to 4, characterized by a relay circuit with the aid of which the engagement of the clutches (8 or 21) and the actuation of the locking lever (15, 25) is controlled. 6. Measuring device according to one of claims 1 to 5, in which the pointers each cooperate with a scale, characterized in that the scale (29) is fixed and the scale (30) with the pointer (2) is movably arranged.