Patent Application
20220098007
The present invention relates in general particularly to vacuum technology-based gripping systems for the dynamic handling of objects. Specifically, the invention relates in particular to vacuum lifting devices as well as corresponding devices for controlling the function of vacuum lifting devices.
Lifting and holding objects (workpieces) by means of vacuum requires vacuum lifting devices. The lifting process is rendered possible by a variable-length suction hose, for example a spiral tube, which is sometimes also referred to as a “lifting tube.” A load handling device which is primarily vacuum-operated, although can also be mechanical, is attached to the end of the variable-length suction hose.
Upon a vacuum lifting device being placed on the workpiece to be moved, the air contained in the vacuum suction device and lifting tube is evacuated and the lifting tube contracts like an accordion such that the workpiece clings to the vacuum suction device and can ultimately be lifted. When the vacuum decreases, the load is then lowered again.
Depending on the application, the vacuum is either generated by a side channel blower, a vacuum pump or a multi-chamber eductor (Venturi nozzle). An operating element attached to the tube lifter's lower end is used to manually control the tube lifter. It enables the one-handed control of the suctioning, lifting, lowering and subsequent release of the load.
Such controllers for vacuum lifting devices are in principle generally known from the prior art. For example, a valve for a vacuum lifting device is known from printed publication DE 202005016147 U1 via which the lifting tube can be vented so that the suctioned object can be set down and released.
The present invention is based on the task of specifying a solution for a particularly ergonomic operation of a vacuum lifting device, whereby a compact design of the vacuum lifting device is in particular desired.
This task is solved by a control device according to independent claim 1 as well as by a vacuum lifting device according to accompanying independent claim 8, whereby advantageous further developments thereof are specified in the respective dependent claims.
Accordingly, the invention relates in particular to a device for controlling the function of a vacuum lifting device, wherein the device comprises an in particular nozzle-shaped distributor block having a first port and a second port, wherein a first flow duct is formed in the distributor block via which the first port can be fluidly connected to the second port when needed by way of a first valve means.
Further provided is for a second flow duct to be formed in the distributor block via which the first port can be fluidly connected to the external atmosphere when needed by way of a second valve means. Furthermore, the invention provides for a further third flow duct to be formed in the distributor block via which the second port can be fluidly connected to the external atmosphere when needed by way of a third valve means.
In other words, the present invention relates in particular to a compact and modular design for the control of a vacuum lifting device, wherein said control enables the actuating, initiating or respectively triggering of all the necessary functions of the vacuum lifting device. The invention is in particular characterized by the distributor block exhibiting a nozzle-shaped body, which allows a modular structure and which in turn also enables short control channels, such that the response characteristic and in particular the response time of the corresponding valve means of the distributor block are optimized.
The in particular nozzle-shaped and modular design of the distributor block further-more ensures an even distribution of weight, this proving to be an advantage with respect to the manual handling of the vacuum lifting device. In addition, the modular structure of the distributor block enables its use in various different vacuum lifting devices.
According to preferential implementations of the inventive solution, it is provided for at least some areas of the distributor block to exhibit an essentially tubular or nozzle-shaped body and be of at least substantially rotationally symmetric design.
The first port is thereby formed on a first end face and the second port is formed on an opposite second end face of the at least partly essentially tubular or nozzle-shaped body. The essentially tubular or nozzle-shaped body preferably has an outer diameter which corresponds at least substantially to the inner diameter of the variable-length suction hose of the vacuum lifting device. This thereby enables the entire distributor block to be integrated within the variable-length suction hose. This results in a particularly compact, low-maintenance and reliable vacuum lifting device as all the valve means are effectively protected from external influences (contamination, moisture, etc.).
The distributor block can comprise a first port region pointing radially from or protruding from the distributor block for the preferably detachable connection of the first valve means, a second port region pointing radially from or protruding from the distributor block for the preferably detachable connection of the second valve means, as well as a third port region pointing radially from or protruding from the distributor block for the preferably detachable connection of the third valve means. The respective port regions are thereby preferably evenly distributed on the outer surface of the distributor block in order to enable an even distribution of weight.
The first, second and third valve means each comprise at least one valve, in particular a throttle valve, whereby said at least one valve is preferably an electromotive valve with a valve drive or a valve operated electromagnetically.
The valve means can thereby be operated particularly precisely and without mechanical effort, which enables an ergonomic as well as fluid lifting and transferring of loads such as, for example, boxes, bags, wood and plastic sheets, sheet metal or glass panes in a wide variety of industries. The lifting and suctioning is thereby executed in a single step in the easiest possible way, resulting in a comfortable working rhythm.
According to one preferential implementation of the inventive control device, at least some areas of the first flow duct fluidly connecting the first port to the second port when needed run along the longitudinal axis of the distributor block, whereby the first flow duct flow can be interrupted when needed, and that by means of a dividing wall which preferably runs vertical or at least substantially vertical to the longitudinal axis of the distributor block as well as by means of the first valve means working in concert with said dividing wall. Thereby able to be provided in a state in which a fluid connection between the first and second port is cut off by way of the first valve means and interacting dividing wall is for the first flow duct to be divided into a first region and a second region separated therefrom.
According to further developments of the latter embodiment, it is provided for the second valve means to be designed to establish a fluid connection as needed between the first region and the external atmosphere, whereby the third valve means is designed to establish a fluid connection as needed between the second region and the external atmosphere.
The invention relates not only to a control device of the aforementioned type but also to a vacuum lifting device particularly having a nozzle-shaped distributor block of the aforementioned type.
According to implementations of the inventive solution, the vacuum lifting device comprises a suction line extending between a vacuum connection and an outlet opening. Although it is entirely feasible for the vacuum lifting device to comprise a mechanical load-handling means, it is preferential for a suction means, particularly in the form of a suction cup, to be used as the load-handling means, whereby said suction means serves the sealing engagement with the surfaces of transport items. The vacuum lifting device furthermore comprises a variable-length suction hose which limits the suction line at least in some areas between the suction means and the vacuum connection.
The load-handling means preferably employed as a suction means is preferably releasably attached to the suction line in an end region of the variable-length suction hose and delimits the outlet opening.
The in particular nozzle-shaped distributor block of the vacuum lifting device thereby serves particularly in the setting of a negative pressure in the suction hose to affect a free flow cross-section of the suction line within a section of line between the suction hose and the outlet opening and/or in the setting of a negative pressure in a section of line between the end region of the suction hose and the outlet opening.
It is advantageously provided for the distributor block to be fully accommodated in the suction hose at the end region of said suction hose. It thereby makes sense for the suction line to be partially formed by the first flow duct of the distributor block.
According to preferential implementations of the inventive vacuum lifting device, an operating device, particularly in the form of a pistol grip, is further provided between the suction means and the end region of the suction hose. It thereby makes sense for the suction means to be pivotably mounted to the operating device in preferably detachable or replaceable manner via a coupling.
Preferentially, the operating device exhibits suitable electrical switches or buttons such as membrane switches or membrane keys, for example, so as to be able to accordingly control the first, second and third valve means. Preferably, the electrical switches or buttons are each connected to the corresponding valve means via an electrical line, whereby the electrical lines are preferentially at least partially integrated or accommodated in the wall of the suction line.
Provided according to a further aspect of the present invention is for the electrical switches or buttons of the operating device to be remotely controllable, in particular via wireless remote control.
Alternatively or additionally, it is provided for the operating device to comprise at least one display or indicator for displaying information relevant to the operation of the vacuum lifting device such as for example the weight force of an object held by the vacuum lifting device, the height between the suction means and the floor, or the position and/or motion data of the vacuum lifting device.
According to a further aspect, the present invention relates to a system having a first vacuum lifting device of the aforementioned type and an optional crane system via which the vacuum lifting device can be positioned at different positions. It is thereby further provided for the system to comprise at least one further second vacuum lifting device, particularly a further second vacuum lifting device of the aforementioned type, whereby the first and at least one second vacuum lifting device are connected to one another via a data transmission channel for transmitting data.
In particular provided with the system according to the invention is for the first and at least one second vacuum lifting device to be designed to communicate and/or exchange data pursuant to the master/slave principle, wherein the first vacuum lifting device, for example, is designed to synchronize operation of the second vacuum lifting device to the operation of the first vacuum lifting device.
So as to be able to operate the aforementioned system according to the invention, the first vacuum lifting device can thus be preferably manually controlled by the operator of the system via the operating device of the first vacuum lifting device, and that by controlling the first, second and/or third valve means of the first vacuum lifting device. The at least one further second vacuum lifting device is thereby preferably controlled automatically, and even more preferentially selectively automatically, particularly in synchronization with the first vacuum lifting device.
The following will reference the accompanying drawings in describing the invention in greater detail on the basis of exemplary embodiments.
Shown are:
The exemplary embodiment of the control device 1 according to the invention depicted in the drawings serves to control the function of a vacuum lifting device.
Such a vacuum lifting device comprises a suction line 102 extending between a vacuum connection and an outlet opening. The vacuum lifting device furthermore comprises a load-handling means which primarily works with vacuum and can be realized as a suction means, particularly in the form of a suction cup, although other mechanical load-handling means are in principle also conceivable. The load-handling means in particular realized as suction means 101 serves the sealing engagement with the surfaces of transport items.
The vacuum lifting device further comprises a variable-length suction hose 100 which at least partially delimits the suction line 102 between the load-handling means 101 particularly realized as suction means 101 and the vacuum connection.
The load-handling means 101 in particular realized as suction means is thereby preferably releasably attached to the suction line 102 at an end region of the variable-length suction hose 100 and delimits the outlet opening, particularly when the load-handling means 101 is realized as a suction means.
To set a negative pressure in the suction hose 100 to affect a free flow cross-section of the suction line 102 in a line section between the suction hose 100 and the outlet opening and/or to set a negative pressure in a line section between the end region of the suction hose 100 and the outlet opening, the inventive control device 1 makes use of an in particular nozzle-shaped distributor block 2.
As can be seen particularly in
As can be seen particularly from the isometric view according to
In the exemplary embodiment according to
The first, second and third valve means 12, 13, 14 each comprise at least one valve, in particular a throttle valve, whereby said at least one valve is preferably an electromotive valve with a valve drive or a valve operated electromagnetically.
In the exemplary embodiment of control device 1, at least some areas of the first flow duct 6 fluidly connecting the first port 3 to the second port 4 when needed run along the longitudinal axis of the distributor block 2. This first flow duct 6 flow can be interrupted when needed, and that by means of a dividing wall 15 which preferably runs vertical or at least substantially vertical to the longitudinal axis of the distributor block 2 as well as by means of the first valve means 12 working in concert with the dividing wall 15. In a state in which a fluid connection between the first and second port 3, 4 is cut off by way of the first valve means 12 and interacting dividing wall 15, the first flow duct 6 is thereby divided into a first region 16 and a second separate region 17.
The exemplary embodiment further provides for the second valve means 13 to be designed to establish a fluid connection as needed between the first region 16 and the external atmosphere 50, whereby the third valve means 14 is designed to establish a fluid connection as needed between the second region 17 and the external atmosphere 50.
The distributor block 2 is advantageously realized as a monolithic component, and in particular made of metal or preferentially plastic.
The distributor block 2 is preferably fully accommodated in the suction hose 100 at the end region of said suction hose 100 of the vacuum lifting device, wherein the suction line 102 of the vacuum lifting device is partially formed by the first flow duct of the distributor block 2. The distributor block 2 with valve means 12, 13, 14 thereby serves in the setting of a negative pressure in the suction hose 100, the setting of a free flow cross-section of the suction line 102 within a section of line between the suction hose 100 and the outlet opening of the suction means and/or the setting of a negative pressure in a section of line between the end region of the suction hose 100 and the outlet opening.
The inventive vacuum lifting device, which as such is not depicted in the drawings, preferably comprises an operating device, particularly in the form of a pistol grip, between the suction means 101 and the end region of the suction hose 100, whereby the suction means 101 is pivotably mounted to the operating device, particularly in detachable or replaceable manner, preferably via a coupling.
The operating device exhibits suitable electrical switches or buttons, in particular membrane switches or membrane keys, so as to be able to control the first, second and third valve means. The electrical switches or buttons are each connected to the corresponding valve means via an electrical line, whereby the electrical lines are preferably at least partially integrated or accommodated in the wall of the suction line 102.
According to a further aspect of the invention, the electrical switches or buttons of the operating device are remotely controllable, in particular partly remotely controllable, for example via wireless remote control.
It can further be provided for the operating device to comprise at least one display or indicator for displaying information relevant to the operation of the vacuum lifting device to the user.
The invention is not limited to the embodiment depicted in the drawings as an example but rather yields from an integrated overall consideration of all the features disclosed herein.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2019 103 251.2 | Feb 2019 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2020/053015 | 2/6/2020 | WO | 00 |
