DE102011011545A1 - Method for supplying fluid e.g. adhesive substance, into joint, involves guiding nozzle by robot along joint, and controlling discharge velocity of fluid based on width, depth and/or grouting depth of joint and/or moving velocity of nozzle - Google Patents

Abstract

The method involves supplying fluid into a joint by a nozzle (4). The nozzle is guided by an industrial robot (1) along the joint. Discharge velocity of the fluid is controlled based on width, depth and/or grouting depth of the joint and/or moving velocity e.g. tool control point velocity, of the nozzle. A layer of the joint and/or the width and/or the depth of the joint are detected by a sensor e.g. charge-coupled device (CCD) sensor. The moving velocity of the nozzle and/or the discharge velocity of the fluid are increased or decreased. An extent of a grouting is determined by the sensor. An independent claim is also included for a device for supplying fluid into a joint.

Description

The invention relates to a method for introducing a fluid into a joint and to an apparatus for carrying out such a method.

In practice, the task often arises of introducing a fluid into a joint or into another depression which has a longitudinal extension, in particular an adhesive or a sealant or another viscous or highly viscous substance. For this purpose, it is known to grout joints by hand, in order to achieve a flat and clean jointing in this way.

The object of the invention is to propose a method of the type specified, which can be carried out by machine, and to provide a device for carrying out such a method.

According to the invention, this object is achieved in a method for introducing a fluid into a joint by the features of claim 1. The fluid is fed to the joint through a nozzle. The nozzle is guided by an industrial robot or other manipulator along the joint. The method can be performed by machine in this way.

The discharge rate of the fluid is controlled as a function of the width of the joint and / or the depth of the joint and / or the jointing depth of the joint and / or the speed of movement of the nozzle. The discharge rate of the fluid is the rate at which the fluid exits the nozzle. This discharge rate, in conjunction with the cross-sectional area of the nozzle and possibly with other parameters, is a measure of the volume flow of the fluid, that is, the amount of fluid that exits the nozzle per unit of time and is introduced into the joint. The discharge rate of the fluid can be generated by a metering pump.

The width of the joint and / or the depth of the joint and / or the joint depth of the joint and / or the speed of movement of the nozzle can be entered as nominal values in a corresponding control and / or regulating device. By the width of the joint and the depth of the joint, generally by the size of the cross-sectional area of the joint in its longitudinal direction, the volume of the joint per unit length is determined. In many cases, the gap is filled over its entire width, but not over its entire depth. The grouting depth indicates up to what depth the fluid is introduced into the joint. The joint depth is smaller or at most equal to the depth of the joint.

The speed of movement of the nozzle is the speed at which the nozzle is moved along the seam.

According to the invention can be determined from the target value of the width of the joint, the target value of the joint depth of the joint and the target value of the movement speed of the nozzle, a target value of the discharge rate of the fluid. The discharge rate of the fluid may be controlled based on this target value.

Alternatively, the object of the invention in a method for introducing a fluid into a joint by the features of the independent claim 2 is achieved. The fluid is fed to the joint through a nozzle. The nozzle is guided by an industrial robot or other manipulator along the joint. The method can be performed by machine in this way.

The speed of movement of the nozzle is controlled as a function of the width of the joint and / or the depth of the joint and / or the jointing depth of the joint and / or the speed of movement of the nozzle.

The width of the joint and / or the depth of the joint and / or the joint depth of the joint and / or the discharge rate of the fluid can be entered as nominal values in a corresponding control and / or regulating device.

From the target value of the width of the joint, the target value of the joint depth of the joint and the target value of the discharge rate of the fluid, a desired value of the movement speed of the nozzle can be determined. The speed of movement of the nozzle can be controlled based on this setpoint. For further details, reference is made to the explanation of the first alternative.

Advantageous developments of the invention are described in the subclaims.

It is advantageous if the position of the joint is detected by a sensor. The sensor may be formed as an area sensor, for example as a CCD sensor, as a CMOS sensor or as another area sensor. In many cases, however, it is particularly advantageous to carry out the sensor as a line sensor. Particularly suitable is a laser line sensor. The line sensor preferably performs a triangulation method. The fact that the sensor detects the position of the joint, the industrial robot can guide the nozzle along the joint. Instead or in addition, the sensor can detect the width of the joint and / or the depth of the joint.

A further advantageous development is characterized in that the discharge speed of the fluid is regulated as a function of the width of the joint and / or the depth of the joint and / or the speed of movement of the nozzle. Instead or in addition, it is possible that the movement speed of the nozzle is controlled in dependence on the width of the joint and / or the depth of the joint and / or the discharge rate of the fluid.

In these cases, the width of the joint and / or the depth of the joint and / or the speed of movement of the nozzle and / or the discharge rate of the fluid are actual values which are determined during the method. The width of the joint can be determined by a sensor, in particular by a line sensor, in particular by a laser line sensor, in particular based on a triangulation method. The depth of the joint can also be determined by a sensor, preferably by a line sensor, preferably by a laser line sensor, preferably based on a triangulation method. The depth of the joint can be determined by the same sensor, which determines the width of the joint.

The speed of movement of the nozzle can also be determined by a sensor, possibly by the same sensor, through which the width of the joint and / or the depth of the joint is determined, but preferably by a separate sensor. Instead or in addition, the speed of movement of the nozzle may be determined from the data and / or control values of the controller of the robot.

The discharge rate of the fluid can also be determined by a sensor, for example by a flow sensor. Instead or in addition, however, the discharge rate of the fluid can also be determined from the data and / or control values of the control of the metering pump or other delivery device of the fluid.

From the determined actual value of the depth of the joint can be determined in particular whether the depth of the joint is less than the joint depth of the joint. In this case, the actual value of the depth of the joint may be used instead of the value of the joint depth in the calculation of the volume of jointing per unit length.

If the actual value of the width of the joint deviates from the desired value of the width of the joint can be adapted by the control and / or regulating device, the discharge rate of the fluid and / or the speed of movement of the nozzle in a corresponding manner. If the actual value of the moving speed of the nozzle deviates from the target value of the moving speed of the nozzle, the discharge speed of the fluid and / or the moving speed of the nozzle can be adjusted by the control and / or regulating device in a corresponding manner. When the actual value of the discharge speed of the fluid deviates from the target value of the discharge rate of the fluid, the movement speed of the nozzle and / or the discharge rate of the fluid can be adjusted by the control and / or regulating device in a corresponding manner.

According to a further advantageous development, the speed of movement of the nozzle is increased or decreased. The speed of movement of the nozzle is preferably increased or decreased stepwise. It is advantageous to increase or decrease the speed of movement of the nozzle by one speed adjustment rate per control interval. The corresponding increased or decreased value of the movement speed forms the new setpoint of the movement speed. This set point may be included in the control of the discharge rate of the fluid as a function of the speed of movement of the nozzle. By increasing the speed of movement of the nozzle, the effectiveness of the method can be increased. By reducing the speed of movement of the nozzle, the method can be adapted to changing conditions.

Instead or in addition, the discharge rate of the fluid can be increased or decreased. The discharge rate of the fluid is preferably increased or decreased stepwise. It is advantageous to increase or decrease the discharge rate of the fluid by one rate of change per control interval. The correspondingly increased or reduced value of the discharge speed forms the new desired value of the discharge speed.

This set point can be included in the control of the speed of movement of the nozzle as a function of the discharge rate of the fluid. By increasing the discharge rate of the fluid, the effectiveness of the process can be increased. By reducing the discharge rate of the fluid, the method can be adapted to changing conditions.

A further advantageous development is characterized in that the extent of the jointing is determined by a sensor. This sensor may be the same sensor that detects the position and / or width and / or depth of the joint and / or the speed of movement of the nozzle. He can but also be a separate sensor. In particular, the sensor can detect the height of the jointing.

A further advantageous development is characterized in that the discharge rate of the fluid and / or the speed of movement of the nozzle are reduced if the degree of jointing is less than a predetermined value. The default value forms a setpoint. In particular, the discharge speed of the fluid and / or the speed of movement of the nozzle can be reduced if the height of the joint deviates from a predetermined value. A reduction in the degree of grout or the amount of grout below a setpoint indicates that the fluid is jammed in front of the nozzle. This is because the rate at which the fluid enters the nozzle is too high, given the density and / or viscosity and / or other parameters of the fluid. The reduction of the discharge rate of the fluid and / or the speed of movement of the nozzle are preferably carried out stepwise. It is advantageous if the discharge speed is reduced by one reduction step size per control interval and / or the movement speed is reduced by one speed adjustment rate per control interval.

According to a further advantageous development, the discharge rate of the fluid and / or the speed of movement of the nozzle is adapted to the offset between the measuring point of the sensor and the application point of the nozzle.

A further advantageous development is characterized in that the manipulated value of the discharge speed of the fluid and / or the speed of movement of the nozzle are compared with the permissible values stored in a characteristic field and, when an unauthorized manipulated value is determined, the manipulated variable or values in the direction of one or more several permissible manipulated variables are changed.

The object underlying the invention is achieved in a device for introducing a fluid into a joint, in particular for carrying out the method according to the invention, by the features of claim 10. The device comprises a device with a nozzle, through which the fluid can be supplied to the joint and which can be guided by an industrial robot along the joint, and a device for controlling the discharge rate of the fluid as a function of the width of the joint and / or the depth of the Joint and / or Groove depth of the joint and / or the speed of movement of the nozzle, and / or a device with a nozzle through which the fluid can be supplied to the joint and which can be guided by an industrial robot along the joint, and means for controlling the Movement speed of the nozzle as a function of the width of the joint and / or the depth of the joint and / or the joint depth of the joint and / or the discharge rate of the fluid, and / or a sensor for detecting the position of the joint and / or the width of the joint and / or the depth of the joint, and / or means for controlling the discharge rate of the fluid as a function of the width of the foot ge and / or the depth of the joint and / or the speed of movement of the nozzle and / or means for controlling the speed of movement of the nozzle depending on the width of the joint and / or the depth of the joint and / or the discharge rate of the fluid and / or means for preferably incrementally increasing or decreasing the speed of movement of the nozzle and / or the rate of discharge of the fluid; and / or a sensor for determining the degree of grout and / or means for reducing the rate of discharge of the fluid and / or the speed of movement of the nozzle the degree of jointing is less than a predetermined value, and / or means for adjusting the discharge rate of the fluid and / or the speed of movement of the nozzle to the offset between the measuring point of the sensor and the application point of the nozzle and / or a device for comparing the Control value of the discharge rate t of the fluid and / or the speed of movement of the nozzle with the one or more stored in a map permissible values and / or means for changing the one or more manipulated values in the direction of one or more allowable control values when determining an invalid control value.

An embodiment of the invention will be explained below with reference to the accompanying drawings. In the drawing shows

1 a device for introducing a fluid into a joint in a side view,

2 a part of the device according to 1 in a side view,

3 the in 2 shown part of the device in a view from the front and

4 a block diagram of the control device for the device according to 1 to 3 ,

In the 1 The apparatus for introducing a fluid into a joint comprises an industrial robot 1 which can be controlled and regulated by several axes. At the extreme arm 2 of the industrial robot 1 is an application device 3 attached in 2 and 3 is shown enlarged.

The application device 3 includes a nozzle 4 that from the industrial robot 1 over a workpiece 5 being moved on a table 6 rests.

The device comprises a reservoir 7 in which a fluid 8th stockpiled, for example, a highly viscous sealant. The fluid 8th is with a barrel pump 9 through a hose 10 to the application device 3 pumped.

Furthermore, the device comprises a dosing control 11 and a robot controller 12 , In the robot controller 12 is also the control and regulating device for the application device 3 intended.

How out 2 it can be seen on the application device 3 a connecting piece 13 attached for the fluid. The free end of the connecting piece 13 communicates with a metering pump (not shown in the drawing) to which the hose 10 from the barrel pump 9 leads. The connecting piece 13 is in connection with a supply line 14 in the application device 3 is provided.

How out 2 and 3 the application device is visible 3 with a sensor 15 provided, which is designed as a laser line sensor. The from the sensor 15 radiated laser beams are denoted by the reference numeral 16 designated. They form a downward, vertical plane.

The supply line 14 in the application device 3 runs diagonally downwards. It opens into the nozzle 4 which runs vertically from top to bottom.

In the workpiece 5 is a fugue 17 with a depth T and a width B present. The jointing depth is denoted by t. It indicates the depth, up to the fluid in the joint 17 penetrates. That in the fugue 17 fluid penetrating to the depth t forms the joint 18 ,

In operation, the fluid passes 8th from the reservoir 7 through the barrel pump 9 in the hose 10 and from there through the metering pump in the connection piece 13 from where it passes through the supply line 14 in the nozzle 4 flows in and from there into the fugue 17 is introduced.

How out 2 the application device becomes apparent 3 when operating in the direction of the arrow 19 moved, in 2 So right. The laser beams 16 of the sensor 15 meet at the measuring point 20 on the fugue 17 , In the direction of movement 19 behind the measuring point 20 is the application point 21 the nozzle 4 , measuring point 20 and application point 21 are spaced apart by the offset V.

The device is after the in 4 operated scheme of the control device operated. In the first regulation 22 become the setpoint for the width B of the joint 17 , the setpoint for the depth T of the joint 17 and the setpoint for the joint depth t of the joint 17 entered. Further, in the first regulation 22 the setpoint of the speed of movement of the nozzle 4 entered, so the set value of the speed with which the nozzle 4 along the fugue 17 to be moved. In the first regulation 22 Further, the target value of the discharge rate of the fluid from the nozzle 4 entered. Together with the cross-sectional area of the nozzle 4 this discharge rate is a measure of the volume flow from the nozzle 4 , which can also be referred to as outflow rate.

In the first regulation 22 Furthermore, actual values are input, namely the actual value of the width B of the joint 17 that from the sensor 15 is determined, the actual value of the depth T of the joint 17 also from the sensor 15 is determined, and the actual value of the movement speed of the nozzle 4 that's from the robot controller 12 can be determined.

From these setpoints and actual values, the first control determines the control values 23 for the discharge rate of the fluid and for the speed of movement of the nozzle 4 , These control values 23 become the second rule 24 fed.

In a map 25 are permissible values for the discharge speed of the fluid and the speed of movement of the nozzle 4 deposited. These permissible values can be stored in the form of a latitude-outflow-rate characteristic map, which can be determined empirically and / or analytically. The map 25 may be permissible values depending on properties of the fluid, in particular its density and / or viscosity, and depending on properties of the joint 17 , in particular of the width B and / or depth T and / or joint depth t included. In particular, the map for each width B of the joint 17 , optionally in dependence of further parameters, a maximum allowable and a minimum allowable discharge speed, for whose determination the fluid dynamic processes can be considered and / or used as a basis.

In the second scheme 24 become the control values 23 the discharge rate of the fluid and the speed of movement of the nozzle 4 compared with the allowable values in the map 25 are deposited. If the control values 23 within the allowable range, become the dynamic memory 26 fed. If the control values 23 outside the permitted range, they are changed. This change takes place in the control interval. The control values 23 be doing in the direction on permissible control values 27 changed. The permissible control values 27 become the dynamic memory 26 fed. In the second regulation 24 can be further measurement parameters 28 received.

In the dynamic memory 26 the discharge rate of the fluid at the offset V between the measuring point 20 of the sensor 15 and the application point 21 the nozzle 4 customized. The dynamic memory 26 calculated from this offset V and the movement speed 29 the nozzle 4 a time delay for the delivery of the fluid from the nozzle 4 to the application point 21 , The movement speed 29 the nozzle 4 can also be referred to as TCP speed ("tool-control-point speed", "tool-center-point speed").

From the dynamic memory 26 become the thus corrected control values of the dosing 11 and the robot controller 12 fed. From the dosing control 11 they reach the dosing system 30 from which the metering pump is controlled to achieve the required discharge rate. From the robot controller 12 the manipulated variables arrive at a manipulator 31 that the movement of the nozzle 4 controls with the required movement speed. On the dosing system 30 and the manipulator 31 can disturbances Z act.

It is possible that the degree of jointing is determined by another sensor (not shown in the drawing). This additional sensor can detect the height of the joint. If this height is less than the desired height, the discharge rate of the fluid and / or the speed of movement of the nozzle are reduced.

The invention provides a method for controlling the discharge rate of a fluid from a metering device with a nozzle and / or the movement speed with which the nozzle of a metering device is moved by an industrial robot. The regulation takes place as a function of the geometric condition of a joint to be jointed, in particular as a function of its width and / or depth and / or jointing depth. The system to be controlled comprises an industrial robot, a metering device and a sensor for determining the joint geometry. It is able to grout a joint, which is not clearly defined in its width and / or depth and may also be subject to certain fluctuations. By the invention, a flush and nacharbeitsfreie jointing can be realized. This is possible even in the most difficult geometric conditions. The process time can be minimized.

The user can variably set various parameters, in particular, the groove depth setpoint, the reduction step size, the increment step size, the control interval and the speed adjustment rate. To calculate the setpoint value of the discharge speed of the fluid, the width of the joint, the current speed of movement of the nozzle and the setpoint value of the joint depth t are used and from this the required discharge speed for the metering device is determined and the value transferred to the latter. In addition, it is monitored whether the setpoint value of the jointing depth t is smaller than the measured joint depth T. If this is not the case, the measured joint depth T can be used as the maximum possible jointing depth.

Furthermore, it can be monitored in addition to the primary control circuit, whether the fluid pushes in front of the nozzle due to the fluid dynamic laws. In this case, the desired discharge rate is too high, so that the volume flow associated with this discharge speed can not be processed by the nozzle. In this case, the discharge rate per control interval can be reduced by the reduction increment. If this case no longer occurs, the discharge speed can again be reduced by the incremental increment to the primary calculated value per control interval.

If the measuring point of the sensor is in front of the application point of the nozzle, a measuring point offset compensation can take place. The calculated values for the discharge speed and / or the movement speed can be temporarily stored and used on the basis of the movement speed and taking into account the inertia of the system only when the calculated value matches the current position of the application point.

Parallel to this, the robot speed, ie the speed of movement of the nozzle, can be adjusted to shorten the process time. For this purpose, it is attempted to increase the movement speed, which can be increased or reduced by the speed adjustment rate per control interval, as far as possible in order to realize the maximum process speed. This regulation intervenes directly in the primary control loop.

To control a width Ausflußraten map can be deposited, which can be determined empirically, sealant-specific and joint-specific. The map can assign to each joint width a maximum and minimum material discharge rate, which arise due to the fluid dynamic processes. The validity range of the calculated manipulated variables can be defined with the stored characteristic field. An area monitoring can be realized which deliberately attempts to adjust the control values again when the validity range is left, so that the process parameters are again within the defined permissible range.

Claims (10)

Method for introducing a fluid into a joint ( 17 ), in which the fluid of the joint ( 17 ) through a nozzle ( 4 ) supplied by an industrial robot ( 1 ) along the joint ( 17 ), characterized in that the discharge speed of the fluid as a function of the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the joint depth (t) of the joint ( 17 ) and / or the speed of movement of the nozzle ( 4 ) is controlled. Method for introducing a fluid into a joint ( 17 ), in which the fluid of the joint ( 17 ) through a nozzle ( 4 ) supplied by an industrial robot ( 1 ) along the joint ( 17 ), characterized in that the speed of movement of the nozzle ( 4 ) depending on the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the joint depth (t) of the joint ( 17 ) and / or the discharge rate of the fluid is controlled. Method according to claim 1 or 2, characterized in that the position of the joint ( 17 ) and / or the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) from a sensor ( 15 ) is detected. Method according to one of the preceding claims, characterized in that the discharge rate of the fluid as a function of the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the speed of movement of the nozzle ( 4 ) and / or that the speed of movement of the nozzle ( 4 ) depending on the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the discharge speed of the fluid is regulated. Method according to one of the preceding claims, characterized in that the speed of movement of the nozzle ( 4 ) and / or the discharge rate of the fluid is preferably increased or decreased stepwise. Method according to one of the preceding claims, characterized in that the extent of jointing ( 18 ) is determined by a sensor. Method according to claim 6, characterized in that the discharge rate of the fluid and / or the speed of movement of the nozzle ( 4 ), if the extent of the jointing ( 18 ) is less than a predetermined value. Method according to one of the preceding claims, characterized in that the discharge speed of the fluid and / or the speed of movement of the nozzle ( 4 ) to the offset (V) between the measuring point ( 20 ) of the sensor ( 15 ) and the application point ( 21 ) of the nozzle ( 4 ) is adjusted. Method according to one of the preceding claims, characterized in that the control value of the discharge rate of the fluid and / or the speed of movement of the nozzle ( 4 ) with the one or more in a map ( 25 ), and that upon determining an impermissible manipulated variable, the manipulated variable or variables are changed in the direction of one or more permissible manipulated variables. Device for introducing a fluid into a joint, in particular for carrying out a method according to one of Claims 1 to 9, characterized by a device with a nozzle ( 4 ) through which the fluid of the joint ( 17 ) and that of an industrial robot ( 1 ) along the joint ( 17 ), and means for controlling the discharge rate of the fluid as a function of the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the joint depth (t) of the joint ( 17 ) and / or the speed of movement of the nozzle ( 4 ) and / or a device with a nozzle ( 4 ) through which the fluid of the joint ( 17 ) and that of an industrial robot ( 1 ) along the joint ( 17 ) and means for controlling the speed of movement of the nozzle ( 4 ) depending on the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the joint depth (t) of the joint ( 17 ) and / or the discharge rate of the fluid and / or a sensor ( 15 ) for detecting the position of the joint ( 17 ) and / or the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or a device for regulating the discharge rate of the fluid as a function of the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the speed of movement of the nozzle ( 4 ) and / or means for controlling the speed of movement of the nozzle ( 4 ) depending on the width (B) of the joint ( 17 ) and / or the depth (T) of the joint ( 17 ) and / or the discharge rate of the fluid and / or a device for preferably increasing or decreasing the speed of movement of the nozzle stepwise ( 4 ) and / or means for preferably gradually increasing the discharge rate of the fluid and / or a sensor for determining the extent of the jointing ( 18 ) and / or means for reducing the discharge rate of the fluid and / or the speed of movement of the nozzle ( 4 ), if the extent of the jointing ( 18 ) is less than a predetermined value, and / or means for adjusting the discharge rate of the fluid and / or the speed of movement of the nozzle ( 4 ) to the offset (V) between the measuring point ( 20 ) of the sensor ( 15 ) and the application point ( 21 ) of the nozzle ( 4 ) and / or a device for comparing the control value of the discharge speed of the fluid and / or the speed of movement of the nozzle ( 4 ) with the one or more in a map ( 25 ) and permissible values and / or a device for changing the manipulated variable (s) in the direction of one or more permissible manipulated variables upon determination of an impermissible manipulated variable.

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