NO771280L - HYDRAULIC SYSTEM. - Google Patents

Description

The present invention relates to a hydraulic system, i

which includes a variable double pump driven by a drive motor where the two pumps each drive at least their own hydraulic motor and where the working pressure for the individual pumps is transferred to a common sensor, suitably a piston device, for sensing.

of the sum of the pumps' emitted power.

By e.g. F1iskantwerk, where boards of varying thickness

keise cantes, the power requirement is proportional to the rnating speed

heat and chipped tile area, i.e. with chipped volume per ten'

unit. In conventional tile edgers, the cutting discs are usually driven by an electric motor via some form of mechanical transmission with a constant ratio. The result is that chopping skis

the speed of rotation of the vein is kept constant. If you want a constant tile length, the rnatation speed must therefore also be kept constant.

In the case of a tile edging of this kind, it can e.g. fore

there is a need to edge boards with a thickness of 16-100 mm. A simple estimate for a constant decay rate then shows that the

the ratio between the maximum required power and the minimum required power can be estimated as:

You then see that approx. 90% of the tables to be edged have

a thickness of between 16 and 25 mm, it is obvious that in a tile edging plant that has a constant feed rate and is dimensionally

nert for the thickest boards, you come for the most common boards

- thicknesses to have a significant power surplus, which is ufc participle e.g. from an economic point of view. For example table me a thickness of 25 mm is utilized below only approx. 25% of that rna};

sima le effect.

The invention aims to provide a hydraulic

system that makes it possible, despite the reduced effect of dri\

the engine' to be able to perform as much work as previously with

the higher drive motor power. The purpose is in particular to provide a hydraulic system that is suitable for e.g. a tile edger or a reducer.

This is achieved according to the invention by further d at least a variable pump, which drives at least one hydraulic motor, has its setting device connected to the sensor via. a coupling device, whereby the current for the additional pump can be varied as a function of the power output of the double pump.

Here, it is particularly advantageous if the setting device for the additional pump is designed in such a way that the pump current is reduced when the power output of the double pump increases.

Adjustment arrangements for the pumps included in the double pump are appropriately connected to each other by means of a regulating yoke, which can be manually adjusted. The regulating yoke can also be connected to the sensor, suitably via the coupling device, whereby the current from the double pump can also be adjusted as a function of the power emitted by the double pump, suitably so that the current decreases with increasing power output.

When a hydraulic system of this kind is used, e.g. for tile edgers or reducers, the double pump can drive processing tools via its hydraulic motors, while the additional pump via one or more motors drives feeding devices for . feeding of at least one workpiece past the processing tool.

With a. hydraulic system of this type is achieved in a simple way. that e.g. the feed rate for a workpiece past the processing tool can be adapted to the selected processing power, expediently, so that the feed rate is reduced when the selected processing power increases. This means that the drive motor can be selected with a relatively small power, which is sufficient for the most commonly occurring works, but that the drive motor, without being overloaded, can also be used for larger works.

Further advantages and characteristics of the invention

will appear from the patent documents and the following detailed description.

The invention shall be explained in more detail in the following with reference to the attached drawings showing an embodiment, where Fig. 1 schematically shows a hydraulic system according to the invention, and Fig. 2 shows a variant of the hydraulic system in Fig. 1.

A hydraulic system designed according to the invention is shown schematically in fig. 1, where a hydraulic system 1 is provided with a drive motor 2, suitably an electric motor, which via a transmission 3 drives two variable pumps 4 and 5, which together form a double pump 6. The two pumps 4 and 5 are each provided with its setting device 7 and 8,. respectively for changing the flow. The two setting devices 7 and 8 are interconnected, by means of a regulating yoke 9, whereby the flow of the two pumps can be changed synchronously. The pump 4 operates via a line 10

at least one hydraulic motor 11 and similarly drives the pump 5 via a line 12 at least one hydraulic motor 13. The two hydraulic motors. 11 and 13 again drive in it. at least each their processing tool 14. By changing the flow in the double pump 6, which e.g. can take place by manual adjustment of the regulating yoke 9, the speed of rotation of the processing tools 14 can be changed as desired.

The lines 10 and 12 are via respective lines 15 and 16 resp. connected to a sensor 17, which senses the sum effect from pumps 4 and 5, i.e. the effect, from the double pump. 6. The sensor 17 is suitably made up of a piston device, where a piston 18, suitably a differential piston, runs in a cylinder housing 19 and on one side is affected by the force from a spring 20 and on the other side is affected by the pressure in the lines 15 and 16. To The piston 18 is connected to a coupling device 21.

The drive motor 2 further drives at least one variable pump 22 via the transmission 3, which in turn drives at least one hydraulic motor 24 via a line 23. In the example shown here, four hydraulic motors 24 are used, each of which drives a feeding device 25 in .an arrangement not described in more detail here

■ for advancing a workpiece past the processing tools 14. The current from the pump 22 can be regulated by means of a setting device 26, which is connected to the coupling device 21 and. thus to the sensor.17.

A skin hydraulic system of the one in fig. 1 type shown is • advantageously applicable, e.g. in circular saw machines, where processing tool 14 consists of circular saw blades. With the aid of the regulation yoke 9, the desired number of revolutions on the circular saw blades can be set, e.g. in a manual way. The drive motor has an appropriate power, which is adjusted for the most commonly occurring work operations, e.g. to split boards with a certain maximum thickness of ice. The sensor 17 has the task of preventing overloading of the drive motor by sensing when feeding even thicker boards past the circular saw blades 14. the total power from pumps 4 and 5 and, with increased power output, to adjust pump 22, so that its flow decreases, which in turn causes the number of revolutions of the hydraulic motor 24 to decrease, with reduced feed power. as a result. This automatically prevents overloading of the drive motor 2.

That in fig. 2 shown hydraulic system differs from the hydraulic system in fig. 1 only in that the regulating yoke 9 is looped and that the setting devices 7 and 8 on the pumps 4 and 5 are now directly connected to the coupling device 21. This results in the flow from the pumps 4 and 5 being automatically adjustable as a function of the total power from the pumps 4 and 5. This automatic flow change entails an automatic change in the speed of the hydraulic motors 11 and 13.' A hydraulic system of this kind is particularly suitable, e.g. at tile edgers or reducers, where the processing tools 14 are made up of f., e.g. chopping boards. The power of the drive motor 2 is accordingly appropriately adjusted to cope with the most commonly occurring work tasks, e.g. to edge boards up to a certain thickness. In order to achieve the correct chip length when feeding in thicker boards, the feed, i.e. the flow from the pump 22 and thereby the speed of the motors 24, follows the speed reduction at the cutting discs 14, so that the chip length is the same for varying board thicknesses.

The hydraulic system shown here can of course be modified in a number of different ways according to need. A hydraulic system of the one in fig. 2 shown type can e.g. is obtained by the regulation yoke 9 in the hydraulic system according to fig. 1, connect

mechanically with the coupling device 21. It is also possible to let the drive motor 2 drive only the pumps 4 and 5, while the pump 22 is provided with a separate operation. Furthermore, of course, the number of hydraulic motors, which are driven by the various pumps, can be varied according to need, as can also the type of processing tool 14 and the rnate arrangement 25.

Claims (9)

1. Hydraulic system which includes one of a drive motor (2) dre- . vet, variable double pump- (.6). where the two pump. (4,5) drives at least each hydraulic motor (11,13) and where the working pressure for the individual pumps (11,13). transferred to a common sensor (17), suitably a piston device, for sensing the sum ■ of the output of the pumps, characterized in that at least one variable pump (22), which drives at least one hydraulic motor (24), has its setting device (26) connected to the sensor (17) via a coupling device ( 21) whereby the further pump's (22) flow can be varied as a function of the power output of the double pump (6). 2. Hydraulic system as specified in claim 1, characterized in that the setting device (26) of the additional pump (22) is designed in such a way that the pump's flow is reduced when the power output by the double pump (6) increases. 3. Hydraulic system as stated in claim 1 or 2, kara k- • teris, in that • the setting system for the pumps included in the double pump (6) is interconnected by means of a regulating yoke (9). 4. Hydraulic system as stated in claim 3, characterized in that the regulating yoke (9) is manually adjustable. 5. Hydraulic system as specified in claim 3, characterized in that the double pump (6) is also adjustable with the help of the sensor (17) appropriately via the coupling device (21), whereby the flow of the double pump is also adjustable as a function of the power emitted by the double pump, appropriately as that the current' decreases with increasing power output. ■ ' 6. Hydraulic system as specified in one of claims 1-5, characterized in that the double pump (6) and the additional pump (22) are driven by the same drive motor (2). 7. Hydraulic system as specified in one of claims 1-6, characterized in that the double pump (6) via its hydraulic motors (11,13) drives processing tools (14) yj -å the further pump (22) via one or more hydraulic motors (24) drives a feeding device for feeding at least one ; ,workpiece past the processing tool (14) whereby the feed rate . the heat is automatically reduced when the output processing power increases. 8'. Hydraulic system as stated in claim 4 and. 7, in particular .for circular saw machines, characterized in that the processing tool (14) consists of circular saw blades. . 9. Hydraulic system as specified in claims 5 and 7, especially for tile edgers and reducers, characterized by . that the processing tool (14) consists of cutting discs..