DE3244832A1 - Counting mechanism - Google Patents

Abstract

The invention relates to a counting mechanism for the determination of the number of revolutions of rotating parts and for the determination of the number of steps of parts moving in steps, particularly for mileometers, elapsed-time meters and cash registers, with connections for a signal source and a subsequent counting mechanism for counting pulses or rotation values. The object of the invention consists in developing the counting mechanism of the said type in such a manner that the counts or measurement data can be measured or detected with a relatively high counting reliability as is given in the case of mechanical counting mechanisms, and in processing the detected data in an electronic unit and displaying them with the aid of this unit without the failure of the supply voltage of this unit having the consequence that the count is deleted and can no longer be reconstructed. According to the invention, this object is achieved by the fact that the counting mechanism is constructed as an electromechanical counting memory which has a mechanical counter part, driven by the part rotating or moving step by step, which carries out the counting process in binary manner and is provided with electromechanical or semi-electronic switching contacts for count determination and storage and which are connected to an electrical evaluator (computer) for the stored count.

Description

Counter

The invention relates to a counter for determining the speed of rotating parts and for the determination of the number of steps of gradually moving parts Parts, especially for odometers, hour meters and cash registers, with connections for a signal source and a downstream counting mechanism for counting impulses or rotation values.

Conventional counting devices usually have a mechanical one Counting mechanism that cannot be read by electronic devices. Commercially available mechanical counters are often driven by a speedometer cable or a linkage, since their installation location usually does not correspond to the location at which the speeds are applied or number of steps are measured, so not in the operating area such with such counting devices provided aggregates lies.

It is known that mechanical counters have a relatively high counting reliability on if that part of the error is guessed by defects in speedometer cables or -Push rods is conditional, is not added.

Furthermore, electronic counting devices are known, which as a rule are characterized in that an electronic circuit clock pulses within a defined cycle time and the result in a semiconductor memory drops. The stored value is then accessible to an electronic calculator made to display this value in different ways can The use of mechanical counters in systems with Electronic units are linked, is disadvantageous in that so far none There is an economically viable option to query the meter reading, and because the connection of the mechanical counter is via a speedometer cable or via a Shift linkage with the respective transducer results in sources of noise and errors Has. Another, albeit less serious, disadvantage is to be seen as that mechanical counters have to be artificially illuminated and as a rule From a purely visual point of view, it is difficult to classify in a fully electronic display field.

However, purely electronic counters also have disadvantages afflicted. So they have a significant error rate and are of a. Supply voltage the failure of which can mean a loss of the meter information.

In addition, counters controlled by microprocessors, if this for the. Motor vehicle operation for displaying or storing the mileage Find use, the possibility cannot be excluded that the counted information incorrectly in permanent storage such as B.

the EEPROM or the so-called shadow RAM can be written like this that the actual mileage can no longer be reconstructed.

The object of the invention is therefore the counter of mentioned type in such a way that the counted values or measured data with the high counting reliability can be measured or recorded, as given with mechanical counters is, and to process the recorded data in an electronic unit and with the help of this unit to display without the failure of the supply voltage this unit or a repair or dismantling of this unit as a result, that the count is deleted and can no longer be reconstructed.

This object is achieved according to the invention in that the counter is designed as an electromechanical counting memory, which has a mechanical, from the rotating or stepwise moving part has driven counter part, who performs the counting process in binary and with electromechanical or semi-electronic Switching contacts for meter acquisition and storage are provided with connected to an electrical evaluator (computer) for the stored meter reading are.

This construction of the counter ensures that its counter part is mechanical and therefore independent of voltage sources, which makes it a high Has interference immunity, but the counting process itself is binary and therefore for the connected electronic computer is already coded, whereby the meter reading information can be saved and fed to the connected computer at any time. at A possible power failure can be remedied by the computer after the power has been restored query the meter reading again immediately and process the determined values. Since it is determined mechanically, the counter reading cannot be impermissible manipulate. Depending on the design, the numerical values can also be applied to the counting elements apply in order to be able to read the counter reading visually in binary form.

Advantageous refinements of the invention are set out in the subclaims marked.

The invention is illustrated below with reference to in the drawing Implementation examples explained in more detail. In the drawing: Fig. 1 shows a schematic Top view of a counter according to the invention with a connected multiplex module, Fig. 2 shows a view comparable to FIG. 3 of one of six counter parts of three each Counter storage elements existing counter, Fig. 3 is a schematic perspective View of a counter part consisting of three counting memory elements of the invention Counter, FIG. 4 is a schematic perspective view of one of a counting spelcher element other configuration than that of Fig. 3 existing counter part of the invention Counter, Fig. 5 is a schematic perspective view of another embodiment a counting memory element with a circuit controlled by a light barrier, 6 shows a schematic perspective view of a further alternative embodiment a counting memory element with one controlled by a magnetic switching element Circuit, Fig. 7 is a schematic perspective view of yet another Embodiment of a counting memory element with one of an ohmic or capacitive one Switching element controlled circuit and FIG. 8 is a schematic perspective View of yet another type of counting spelcher element according to FIG. 5, with a circuit controlled by an inductive switching element.

The schematic plan view of the counter 1 shown in FIG. 1, which is driven by the speedometer cable 3, leaves a connected multiplex module 2 recognize who has the task of counting the number of between the counter part and the the counting pulses processing, not shown electronic unit running To reduce lines 4 and thereby simplify the structure of the counter.

In Fig. 3 is designed as an electromechanical counting memory Counter shown with a counter part, which is an octagonal seated on an axis 5 Has memory element 6, the marginal edges of which run from corner to corner of the octagon, formed as electrical conductors 8, flat contact surfaces 10-17, which can be scanned by contact elements 9 brought up to the memory element. These Contact elements are connected to a computer (not shown) via conductors 4. A part of the flat contact surfaces 10-17 is against one another by means of insulators 7 electrically isolated.

Three such storage elements 6, denoted here by 19, 20 and 21 are arranged in this embodiment on the axis 5 one behind the other and firmly connected. They are around at least one contact area each further rotatable with the axis in the direction of the arrow. Any such storage element is designed as an octagonal, equilateral plate and thus on its circumference provided with eight flat contact surfaces 10-17, which correspond to the octal number system enable counting from 0 - 7, the respective count value being binary via the contact elements 9 can be scanned.

The counter part 5 shown in Fig. 3 consists of three similar, disk-shaped storage elements, hereinafter referred to as ASCOM element for short. Such an ASCOM element can come from a wide variety of signal sources, such as speedometer cables or push rods, driven by a drive element shown schematically at 3 will. Do the ASCOM element is increased by one with each signal pulse Position or one digit is switched and thus changes its binary status.

The counting memory shown in FIG. 4 is basically that in FIG. 3 shown is the same except that it has the configuration of a cube and the counts thus not based on the octal number system.

In the embodiment of the electromechanical shown in FIG Counting memory are six counter parts 22, 23, 24, 25, 26, 27 of those shown in FIG Art, thus each consisting of three octagonal, equidistant 1-plate-shaped Storage elements 19, 20, 21, fixedly arranged on a common axis 5, with which they from a drive, not shown, in the direction of the arrow around the longitudinal axis the axis 5 are rotatable, the contact elements in this embodiment are connected to eighteen contact lines, the flat contact surfaces of the storage elements scan. Here, too, the first part of the counter becomes the first part of the counter for each signal pulse 22 moved by elne position or by one digit and thus changes its binary Status. If the counter value has to be transferred to the next digit, the next Counter part 23 moved on by one position or place until this counter part too has passed through the digits 0 - 7, whereupon the next counter part 24 operates is etc. until the last counter part 27 is reached. The ones used here in total eighteen lines for forwarding the binary information make it possible for this configuration (18 bit resolution), a number range from 0 - 262.144 (p.13) to represent.

Jeodch is with appropriate expansion of this system by adding further counter parts or ASCOM elements, which in this case each count from 0 - 7 enable any other number range to be recorded. In any case it will the counted and stored information binary via the contacts 9 on the connected Transfer computer. Since the entire system is only used to determine data and not Must switch power, are the requirements on the individual contacts, for example Spring elements can be very small.

Each ASCOM element consists of an electrically conductive material, and the current is fed to the element via axis 5 (Fig. 2 and 3), its flat contact surfaces, as explained above, according to the one used Number system and the number of existing contact surfaces either as insulators 7 or electrical conductors 8 (Fig. 3) are formed. The number of contact levels stands with the number of storage elements 19, 20, 21 (Fig. 3) in the following mathematical Relationship: number of contact levels of a storage element = second power of Number of storage elements.

The electromechanical counting memory can also be used instead of a mechanical tapping of the storage element or elements by means of contact elements Have counter part which, as can be seen from Fig. 5, consists of a body 30, which has a light shaft 31 and one of the speed to be counted or Steps to be counted transferring, not shown drive with a shaft 32 is rotatable, on the opposite side of the body from the light source 33 30, a photosensitive element 34 is arranged, which depending on the Rotational position of the body 30 produces a circuit to the connected computer or interrupts.

Instead of the opto-electric counter part shown in FIG also use a counter part (Fig. 6), the from one with one Shaft rotatably mounted, driven disk 35 is made on two opposite Sides has a magnet 36 and outside of the disc one a circuit to the connected computer opening or closing magnetic switch 37, for example a reed contact or hall effect switch. The embodiment shown in FIG an electromechanical counting memory according to the invention shows that such a Counting memory can in principle also be implemented in that the counter part is formed by a disk 38 rotatably mounted on a shaft 32, which on at least two opposite sides of electrical resistance elements or capacitance surfaces 39 has which are scanned by at least one contact element 40 that is in turn connected to a computer, not shown. Using of resistance elements in this embodiment are those opposite one another Elements 39 high or low resistance.

Finally, the electromechanical counting memory can also be used Realize the embodiment shown in Fig. 8 * in the case of an indirect Connection of the counter part with the computer is not a capacitive or ohmic one Coupling, as in the embodiment according to FIG. 6, takes place, but by an inductive one Coupling. Here, the counter part of a body 41 and one located in this Coil 42 is formed, which can be rotated by a drive with the shaft 32.

Outside the body 41 there is another coil 43 which depending on the rotational position of the body 41 by the induction field of Coil 42 is excitable.

The second coil cannot flow current to one in this way allow or interrupt the computer shown.

In this embodiment, an ASCOM element is necessary for each binary digit, but it has the advantage that it does not require any mechanical contacts.

Claims (11)

Claims 1. Counter for determining the speed of rotating rush and for step counting of gradually moving parts, especially for odometers, hour meters and cash registers, with Connections for a signal source and a downstream counting mechanism for Counting of impulses or rotation values, which is not shown that the counter is designed as an electromechanical counting memory, the one mechanical, driven by the rotating or stepwise moving part Has counter part (1), which carries out the counting process in binary and with electromechanical or semi-electronic switching contacts for determining and storing the meter reading is provided with an electrical evaluator (computer) for the stored Meter reading are connected. 2. Counter according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the counter part (1) is connected to a multiplex module (2), the the number of between the counter part and one of the counting pulses processing lines running through the electronic unit. 3. Counter according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the counter part (1) has at least one seated on an axis (5) Memory element (6) has, the edge edges of which are curved or flat, as electrical Conductor (8) formed contact surfaces (10-17) limit which of the memory element brought in contact elements connected to the computer via conductors (9,34,37,42,44) can be scanned and which are partially electrically connected to one another by means of insulators (7) are isolated. 4. Counter according to claim 3, d a d u r c h g e k e n n -z e i c h n e t that the counter part consists of three on the axis (5) arranged one behind the other, storage elements (19, 20, 21) of the same type and firmly connected to one another are made, which can be further rotated by at least one contact surface, each Storage element is designed as an octagonal, equilateral plate and thus on its scope has eight contact levels (10-17), which correspond to the octal number system enable counting from 0 to 7, whereby the respective count value is binary via the Contact elements can be scanned. 5. Counter according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the counter part consists of a body having a light switch (31) (30) is formed by a number of revolutions to be counted or steps to be counted transmitting drive is rotatable with an axis (32), on which the light source (33) opposite side of the Body (30) a photosensitive Element (34) is arranged, which depends on the rotational position of the body (30) creates or interrupts a circuit to the connected computer. 6. Counter according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that the counter part consists of a rotatably mounted with a shaft (32), driven disc (35) consists of one on two opposite sides Has magnet (36) and outside the disk a circuit to the connected Computer opening or closing magnetic switch (37). 7. Counter according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the counter part is rotatably supported by a shaft (32) Disc (38) is formed, the electrical on at least two opposite sides Has resistance elements or Kapazltätsflächen (39) through at least one Contact element (40) can be scanned. 8. Counter according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the counter part of a body (41st) and one located in this Coil (42) is formed, which are rotatable by a drive with an axis (32), and that outside the body (41) a further coil (43) is arranged, which in Depending on the rotational position of the body (41)) by the induction field of Coil (42.) can be excited. 9. Counter according to one of claims 1 to 8, d a d u r c h g e k It is noted that several memory elements each consist of three memory elements Counter parts arranged on a common axis and rotatable with respect to one another are. 10. Counter according to one of claims 1 to 9, d a -d u r c h g e It is not indicated that the counter part can be connected to a speedometer cable (3) which has a mechanical pulse generator. 11. Counter according to one of claims 1 to 9, d a -d u r c h g e It is not indicated that the counter part can be connected to a mechanism (3) that has a mechanical pacemaker.