DE1499609C3 - Magnetic tape recorder - Google Patents

Description

The invention relates to a magnetic tape device in which several tape units, each consisting of one Magnetic tape with associated tape reels and transducers are arranged in a common plane and the tape drive of each individual tape unit, independently of the others, by coupling a common drive takes place.

In a known magnetic tape device of this type, all existing tape units are in one Row arranged one behind the other. This arrangement is well suited for magnetic tape memories with shortened access time because it corresponds to the purpose of use extremely short magnetic tapes with a simplified tape guide can be used.

It is known that high-quality, high-speed magnetic tape devices with vacuum columns are required as tape storage devices to compensate for and regulate the tape speed. These tape stores require a relatively large amount of space even with a single tape unit and, in addition, a pneumatic line system which is connected to one or more negative pressure sources. It is clear that in a magnetic tape device constructed according to known aspects and having η tape units, the total space requirement would correspond to η times that of an individual tape unit.

The invention is based on the object of providing a magnetic tape device with a plurality of tape units each belt unit has its own vacuum columns, significantly more space-saving than previously possible to build in one level, and all vacuum columns avoiding a complex Line system to be connected directly to a common vacuum source.

According to the invention this object is achieved in that the magnetic tapes of all tape units are guided between the coaxially superimposed tape reels via two vacuum columns, which are grouped in sector-shaped fields around a central vacuum source as the center are, the vacuum columns of each belt unit parallel to each one vacuum column of the neighboring Run tape unit and with these have a common partition and the tape reels, Converter, guide and transport means of each belt unit between its associated vacuum columns lie.

This sector-shaped arrangement of the tape units is particularly useful in high-quality magnetic tape devices many advantages. By merging vacuum partitions, building elements are created and above all saved space. Furthermore, the sector-shaped arrangement allows installation a much simplified vacuum line system.

It is preferably provided that the sector-shaped delimited fields are squares, one a different division and a different number of tape units or fields is, however, no problem possible. For preferably separate control of the winding and unwinding speeds of the tape reels Each unit is in each vacuum column one inside and one outside of a loop with which the magnetic tape is attached the vacuum column passes through, located vacuum switch arranged. In the case of the sector-shaped The overall conception of the magnetic tape recorder also results from the connection lines of these vacuum switches a simple line structure.

The invention is explained in more detail below with reference to the preferred exemplary embodiment shown in the drawings. It shows
1 shows a plan view of a magnetic tape device with a plurality of tape units, with part of the cover plate being removed.

F i g. 2 a schematic view of the arrangement of the tape reels and their regulating devices,

F i g. 3 is a schematic representation of the vacuum source for the device according to FIG. 1 and

F i g. 4 is a schematic representation of an arrangement for driving the tape drive shafts of FIG Magnetic tape device according to Fig. 1.

! The one described below with reference to the drawing Magnetic tape recorder has four tape units or tape units arranged in a horizontal plane. Fields on. Each tape unit of the tape device is known per se; the invention is based on the structural Arrangement of these components in a single compact unit directed.

The four tape units or fields are generally designated A, B, C and D and are arranged in the vicinity of the four corners of the housing of the magnetic tape device, which is not shown here. As can best be seen from FIG. 2, each field A, B, C and D has two coaxially mounted tape reels 10 and 11. The tape reels 10 and 11 are mounted coaxially on drive shafts 10a and 11a and are driven by individual motors. A motor 12 drives the tape reel 10 provided, for example, as a supply reel for the magnetic tape T via the drive shaft 10a, while a motor 13 drives the tape reel 11 serving as the take-up reel via the drive shaft 11a. The motors 12 and 13 are each assigned control circuits 14 and 15, which regulate the tape winding and unwinding speed of the tape reels 10 and 11 in a known manner in accordance with a control signal. The regulating or control circuit 14, which is assigned to the motor 12 of the supply reel 10, is connected to a short loop sensing device 16 and a long loop sensing device 17. In the same way, the rule or Control circuit 15 regulated by a short loop sensing device 18 and a long loop sensing device 19. The loop sensing devices 16 to 19 supply a signal which indicates whether the loop length of the magnetic tape T is either too long or too short for the intended operating case. For this purpose, the magnetic tape T is guided in a loop through a vacuum chamber, wherein, as will be explained in more detail below, vacuum switches supply control signals in accordance with the length of the loop. The control circuits mentioned and the other conventional control devices for the tape units are arranged below the tape reels and are not shown in detail since they are not essential for understanding.

To regulate or control the loop lengths of the magnetic tape, four double vacuum chambers are provided at each field A, B, C and D , which are designed in accordance with the vacuum chambers located in the vicinity of field A, denoted by 20 and 21. The double vacuum chamber 20 is arranged between the fields A and D , while the vacuum chamber 21 lies between the fields A and B. A corresponding double vacuum chamber 22 is arranged between fields C and D , and the fourth double vacuum chamber 23 lies between fields B and C. The four double vacuum chambers 20-23 are connected to a single vacuum source 24. As shown, the four double vacuum chambers 20 to 23 intersect at a point approximately in the middle of the housing and are in communication with the vacuum source 24 (see FIG. 3). The other connection of the vacuum source 24 is a line 25 through which the vacuum system is closed. The vacuum source 24 comprises a filter 26 which is intended to clean the air circulating in the vacuum system.

The general structure of the vacuum chambers is known. Suffice it to say, therefore, that each double vacuum chamber is equipped with two vacuum switches, which serve as short and long loop sensors for each of the vacuum chambers. In the following, reference should be made to the double vacuum chamber. It can be seen that this vacuum chamber 20 ^{comprises two separate vacuum columns 20 Λ} and 20 °. The vacuum column 20 · ⁴ is provided with an opening 20 for actuating the ⁴ ^ to the short length of the tape loop in the vacuum column 20 ^Λ indicating Vakuumschaiters. In the same way, an excess length of this tape loop is indicated when a switch is operated via an opening 2ti ^A - ^L on the opposite side of the vacuum column. The vacuum column 20 ^D forms the other half of the double vacuum chamber 20 and has similar openings 20 ^D - ^u and 2Q ^D - ^L for correspondingly indicating a loop that is too short and one that is too long the vacuum source 24 is capable of maintaining a pressure differential between the opposite sides of the belt loop. If the tape loop runs beyond one of the openings 20 ^AU or 20 ^{· the corresponding tape reel drive} is accelerated or decelerated accordingly by a signal. The other tape reel of the tape reel pair of the tape unit A is controlled by the double vacuum chamber 21 and in particular by its vacuum column 21 ^Λ . The vacuum column 21 ^Λ is equipped in a corresponding manner with openings 21 ^ and 21 ^Λ - ^{ί /} through which the switches indicating the loops that are too long or too short are operated. The more precise design of this control device can be found in the aforementioned US Pat. No. 2,921,753.

As in Fig. 1, the belt unit A is represented by the vacuum columns 20 ^A and 21 ^X , the belt unit B by the associated vacuum columns 21 ^ß and 23 ^{ß of} the double vacuum chambers 23, the belt unit D by the vacuum column 20 ^D and the vacuum column 22 °, not shown double vacuum chamber 22 and the belt unit C by the vacuum columns 22 ^C and 23 ^C controlled.

As shown in Fig. 1, the transducers and tape guides are arranged in a conventional manner, with a precisely machined plate 30 being provided as a support for each field. A transducer 31 is mounted on the plate 30 near the pair of tape reels of the field A , with guide elements 32 being arranged on both sides. The tape drive shafts 33, 34 for forward and reverse are arranged on the two opposite sides of the transducer 31. The drive shaft 3 for the advance of the magnetic tape interacts with a pressure roller 35, and in the same way the drive shaft 34 is provided with a pressure roller 36 for the return of the magnetic tape. The magnetic tape T runs from one of the tape reels, namely the supply reel 10, over a guide element 32 into the vacuum column 21 ^Λ and forms a loop between the openings 21 ^ - ^ and 21 ^Λ - ^£. Thereafter, the magnetic tape T comes out of the vacuum column 21- ^4, running between the drive shaft 33 and pinch roller 35 therethrough, is moved past the transducer 31 and passes between the

Drive shaft 34 and pressure roller 36. From this tape drive device, the magnetic tape T is introduced into the vacuum column 2w ^A , forms a loop between the openings 2ß ^AU and 2ß ^A - ¹ and is then led out of the vacuum column and onto the take-up reel 11 of the tape unit A. wound up.

It is essential that the front drive shaft 33 and the rear drive shaft 34 of each belt unit are driven by their own drive motors, but by a single drive motor. F i g. 4 shows an example of driving each of the drive shafts by a single motor. For this purpose, the motor designated 40 is coupled to each of the drive shafts of the four belt units by means of a single, endless drive belt 41. The forward and reverse drive shafts 33 and 34 are provided with corresponding index characters A, B, C, D , which indicate which field A, B, C or D they are assigned to. For example, reference numeral 33 ^Λ denotes the forward drive shaft of field A, while reference numeral 34 ^Λ denotes the reverse drive shaft of field A. A guide 42, which changes the direction of the drive belt 41, is provided between the drive shafts 33 and 34. The guide 43, which is provided near the motor 40, is made movable and controls the tension of the drive belt 41.

1 sheet of drawings

Claims (7)

Patent claims: 1. Magnetic tape device in which several tape units, each consisting of a magnetic tape with associated tape reels and transducers, are arranged in a common plane and the tape drive of each individual tape unit takes place independently of the rest by coupling to a common drive, characterized in that the Magnetic tapes (T) of all tape units between the coaxially superposed tape reels (10, 11) are each guided over two vacuum columns (20 A, 21 A; 21 B, 23 B; 20 D, 22 D; 22 C, 23 C), which in Sector-shaped delimited fields (A, B, C, D) are grouped around a central vacuum source (23) as the center point, the vacuum columns of each belt unit running parallel to a respective vacuum column of the adjacent belt unit and with these having a common 'partition, and the Tape reels, transducers, guide and transport means of each tape unit lie between their associated vacuum columns. 2. Magnetic tape device according to claim 1, characterized in that the sector-shaped delimited fields (A, B, C, D) are squares. 3. Magnetic tape device according to claim 1 or 2, characterized in that the axis of two superimposed tape reels (10, 11) passes through at least one diagonal of the associated field (A, B, C, D). 4. Magnetic tape device according to one of claims 1 to 3, characterized in that all tape units are arranged on a common plate. 5. Magnetic tape device according to one of claims 1 to 4, characterized in that the tape reels (10, 11) of each tape unit can be driven separately and their winding and unwinding speeds can be regulated with the aid of control elements connected to the vacuum columns (20 A ...) . 6. Magnetic tape device according to claim 5, characterized in that in each vacuum column (20 Λ, 21A; ... ) A vacuum switch (20 ^AU , 2ti ^AL ; .. ) inside and outside a loop with which the magnetic tape passes through the vacuum column, located vacuum switch. .) is arranged. 7. Magnetic tape device according to one of claims 1 to 6, characterized in that a central air filter (26) is located in the main flow of the vacuum system.