阅读说明：本技术 打印机滑架 (Printer carriage ) 是由 L·索雷恩莱奇 R·奥尔特拉拉米雷兹 J·A·维拉桑特朋比伯雷 J·加尔西亚马蒂尼兹 于 2018-09-14 设计创作，主要内容包括：公开了一种例如用于打印系统的包括壳体的滑架,所述滑架是沿滑架引导件移动的滑架,所述滑架包括附接到所述滑架的驱动机构。所述驱动机构包括具有旋转轴的马达和附接到所述旋转轴的中间元件,所述中间元件是接触所述滑架引导件的中间元件,以便使所述滑架沿所述滑架引导件移动。(A carriage including a housing, such as for a printing system, is disclosed, the carriage being a carriage that moves along a carriage guide, the carriage including a drive mechanism attached to the carriage. The drive mechanism includes a motor having a rotation shaft and an intermediate member attached to the rotation shaft, the intermediate member being an intermediate member that contacts the carriage guide so as to move the carriage along the carriage guide.)

1. A carriage including a housing, the carriage being a carriage that moves along a carriage guide, the carriage comprising:

-a drive mechanism attached to the carriage;

wherein the driving mechanism includes a motor having a rotation shaft and an intermediate member attached to the rotation shaft, the intermediate member being an intermediate member that contacts the carriage guide so as to move the carriage along the carriage guide.

2. The carriage of claim 1, wherein the intermediate element comprises a rubber wheel.

3. The carriage of claim 1, wherein the intermediate element comprises a gear having teeth complementary to a set of teeth provided in the carriage guide.

4. The carriage of claim 1, wherein the motor is a servo motor.

5. The carriage of claim 1, further comprising a position sensor to determine a position of the carriage along the carriage guide.

6. The carriage of claim 5, wherein the position sensor comprises an encoder associated with the rotational axis.

7. The carriage of claim 5, wherein the position sensor comprises an optical sensor.

8. A printing system, comprising:

-a print medium support surface supporting a print medium;

-a carriage comprising a housing to receive a print head comprising a set of nozzles to eject printing fluid towards the print medium;

-a carriage guide extending in a driving direction of the print medium supporting surface; and

-a drive mechanism driving the carriage in the drive direction;

wherein the drive mechanism comprises: a motor fixedly attached to the carriage; and an intermediate element that converts the rotational motion imparted by the motor into linear motion of the motor along the carriage guide.

9. The system of claim 8, wherein the intermediate element is a rubber wheel for contacting the carriage guide.

10. The system of claim 8, wherein the carriage guide includes a set of teeth and the intermediate element is a gear having teeth complementary to the set of teeth of the carriage guide.

11. The system of claim 8, further comprising an alignment rod parallel to the guide, and wherein the carriage is slidingly attached to the rod.

12. The system of claim 11, wherein the carriage includes an aperture to receive the rod.

13. The system of claim 8, further comprising a position detector to determine a position of the carriage relative to the carriage guide.

14. A method of driving a carriage of a printer in a drive direction, wherein the carriage comprises a motor attached to the carriage for movement therewith in the drive direction, the method comprising:

-energizing the motor to produce a rotational movement along a rotational axis; and

-positioning an intermediate element between the rotation axis and a carriage guide for converting the rotational movement into a linear movement along the carriage guide.

15. The method of claim 14, wherein the intermediate element is a rubber wheel.

Background

In a printing operation of the printing device, a carriage including a print head is moved relative to the print media article to eject printing agent from the print head onto the print media article. The carriage is movable along a carriage guide and is advanceable along the carriage guide by a drive mechanism. For example, the carriage described above may be used in printing devices for printing ink, as well as in 3D printing devices, in which layers of build material are selectively cured by layers with printing fluid that is printed onto the layers of build material.

Similarly, in a scanning operation of a scanning apparatus, which may be included in a multifunction printer (MFP) and other apparatuses, a document to be scanned is placed on a transparent window for scanning. The document may be placed face down (i.e., where "face" refers to the side of the document to be scanned) on one side of the window. The carriage with the scan bar coupled thereto, which includes optics for scanning the document, may then be moved along the length of the opposite side of the window, for example along the carriage bar. The carriage and thus the scan bar may be advanced along the carriage bar by a drive mechanism comprising a motor and a flexible belt.

Drawings

Various exemplary features will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, in which:

fig. 1 shows a perspective view of one example of a carriage, in this case for carrying a print head of a printing system.

Fig. 2 shows a detailed view of the example of fig. 1.

Fig. 3 shows a side view of the carriage of fig. 1 and 2.

Fig. 4 illustrates the movement achieved by one example of a carriage according to an example.

Fig. 5 shows a perspective view of another example of a carriage for a printing system.

Detailed Description

In the following description and the annexed drawings, certain illustrative embodiments of a printing device, a printing system, and/or a printer are described. In examples described herein, a "printer" or "printing system" may be a device that utilizes printing material (e.g., ink or toner) to print content on physical media (e.g., paper, fabric, powder-based build material layers, etc.). For example, the printer may be a broadframe printing device that prints latex-based printing fluid on a print medium, such as a print medium having a size of a2 or greater. In some examples, the physical media on printing may be a web roll or a pre-cut sheet. In the case of printing on a layer of powder-based build material, the printing apparatus may utilize deposition of the printing material in a layer-by-layer additive manufacturing process. The printer may utilize suitable printing consumables such as ink, toner, fluid or powder, or other raw materials for printing. In some examples, the printing device may be a three-dimensional (3D) printing device. One example of a fluid-printable material is an aqueous latex ink that may be ejected from a printhead, such as a piezoelectric printhead or a thermal inkjet printhead. Other examples of printing fluids may include dye-based color inks, pigment-based inks, solvents, brighteners, fixers (fixer agents), and the like.

In one example, the present disclosure describes a carriage for use in a printing device. However, in another example, the carriage of the present disclosure may be incorporated in a scanning device.

The carriage disclosed herein includes a drive mechanism for advancing the carriage in a drive direction when printing a document, and may include a coupled printhead. In the present disclosure, the carriage comprises a motor fixedly attached to the carriage, i.e. the motor moves in the driving direction together with the carriage.

Similarly, in the case of a scanning device, a drive mechanism for advancing a carriage to which a scan bar is coupled when scanning a document includes a motor coupled to the carriage so as to move with the carriage when the motor is activated.

Accordingly, there is hereby disclosed a carriage comprising a housing, the carriage being a carriage moving along a carriage guide, the carriage comprising:

-a drive mechanism attached to the carriage;

wherein the driving mechanism includes a motor having a rotation shaft and an intermediate member attached to the rotation shaft, the intermediate member being an intermediate member that contacts the carriage guide so as to move the carriage along the carriage guide.

An example of an intermediate element may be a rubber wheel or a pinion-and-rack assembly, i.e. the intermediate element comprises a gear wheel having teeth complementary to a set of teeth provided in the carriage guide.

Further, the motor may be a servo motor.

In one example, the carriage may comprise a position sensor, such as an optical sensor, or an encoder, associated with the motor, in particular with the rotation axis activated by the motor, to determine the position of the carriage along the carriage guide.

Further, disclosed herein is a printing system comprising:

-a print medium support surface supporting a print medium;

-a carriage comprising a housing to receive a print head comprising a set of nozzles to eject printing fluid towards the print medium;

-a carriage guide extending in a driving direction of the print medium supporting surface;

-a drive mechanism driving the carriage in the drive direction;

wherein the drive mechanism comprises: a motor fixedly attached to the carriage; and an intermediate element that converts the rotational motion imparted by the motor into linear motion of the motor along the carriage guide.

In one example, the intermediate element is a rubber wheel for contacting the carriage guide. In another example, the carriage guide includes a set of teeth and the intermediate element is a gear having teeth complementary to the set of teeth of the carriage guide.

The system may further comprise an alignment rod parallel to the guide, and wherein the carriage is slidingly attached to the rod. In one example, the carriage includes an aperture to receive the rod.

In one example, the carriage includes a position detector to determine a position of the carriage relative to the carriage guide.

Furthermore, a method of driving a carriage of a printer in a driving direction is disclosed, wherein the carriage comprises a motor attached to the carriage for moving in the driving direction together with the carriage, the method comprising:

-energizing the motor to produce a rotational movement along a rotational axis; and

-positioning an intermediate element between the rotation axis and a carriage guide for converting the rotational movement into a linear movement along the carriage guide.

In one example of the method, the intermediate element is a rubber wheel, however, in other examples, the intermediate element may be a rack-and-pinion assembly.

Fig. 1 shows an example of a carriage 2 used as part of a printing system 1. In the example of fig. 1, a portion of a printing system 1 is shown, with some elements removed to increase the understandability of the figure. The printing system comprises a carriage 2 for housing a printing element, such as a printhead 7, or in another example a scanner. The printing system comprises a beam 3 having a length defining the travel distance of the carriage 2, in particular the beam 3 comprises a carriage guide 5, the carriage guide 5 guiding the carriage along its movement.

The system may also comprise an alignment bar 6 to ensure alignment of the carriage relative to the beam 3. In one example, the alignment bar is surrounded by the carriage such that the carriage 2 slides along the bar 6.

Furthermore, the carriage 2 of fig. 1 also comprises a drive mechanism or propulsion mechanism, which is fixedly attached to the carriage 2, i.e. which in operation moves together with the carriage 2. The drive mechanism of fig. 1 comprises an actuator, e.g. a motor 4 and an intermediate element 40, which will be explained in more detail with reference to fig. 2 and 3.

Fig. 2 and 3 show detailed views of fig. 1, focusing on the drive mechanism of the carriage 2. Fig. 2 and 3 show that the drive mechanism comprises a motor 4, which motor 4 via an intermediate element 40 contacts the carriage guide 5 for pulling against it, so that the movement of the carriage 2 together with the drive mechanism along the carriage guide is effected.

Furthermore, the alignment rod 60 is shown in more detail, which is received by a hole 60 provided in the carriage to allow the carriage to be displaced along the rod 6 to ensure its alignment.

As can be seen, in particular in fig. 3, the carriage guide 5 may be a U-shaped or L-shaped profile, which is rigidly attached to the beam 3 to provide a stepped surface having: an upper surface separated from the beam by a large distance; and a lower surface, which corresponds to the beam 3 or is closer to the beam than the upper surface. Such a configuration allows the system to accommodate elements with a large volume, such as the motor 4, or even the carriage in the lower surface, while the upper surface contacts the intermediate element 40 for moving the carriage. Furthermore, such a construction can also be made so that the traction is performed on the upper half of the carriage, and preferably substantially at a height corresponding to the centre of mass of the carriage, further helping to align the carriage 2 along its movement.

Fig. 4 shows functions of an example of a drive mechanism for the printing system 1. In the example of fig. 4, the drive mechanism comprises a motor 4, for example a servomotor, which may be supplied by an energy source via a Pulse Width Modulated (PWM) signal. In response to receiving energy from the energy source, the motor 4 may generate rotational motion (R) along the shaft. The motor may then comprise an intermediate element 40 to transform this rotational movement (R) into a linear movement (D) along the carriage guide 5. In the example of fig. 4, this is achieved by: a friction surface is provided between the carriage guide 5 and the rotation shaft, in particular by using a rubber wheel as the intermediate element 40. In one example, the rack 50 may be a plastic or rubber rack. In addition, the pinion gear or intermediate member 40 may also be a plastic or rubber gear.

In this example, the rubber wheel is drawn against the carriage guide 5, so that a linear movement in the drive direction (D) is achieved. In another example, the carriage guide 5 may further comprise a booster, such as a coating and/or a plastic component, to increase the friction between the guide 5 and the intermediate element 40, thereby preventing slippage.

Furthermore, in one example, the carriage 2 may also be provided with a position sensor that moves together with the carriage 2. The sensor may be an optical sensor to assist in determining the relative position of the carriage 2 along the guide 5 and may include a communication channel with a processor within the system to provide position information of the carriage 2 to the system. In another example, the position sensor may comprise an encoder associated with the motor 4, which may assist in determining the position of the carriage 2 along the guide 5.

The carriage 2 comprises a housing for receiving a print head comprising a set of nozzles to eject printing fluid towards a print medium in one example. In other examples, the carriage 2 may be associated with a scan bar and may be moved along the length of the substrate in order to scan it.

Fig. 4 shows another example of a drive mechanism according to an example. In the example of fig. 4, the drive mechanism comprises a motor 4, which motor 4 has a rotational shaft 401 activated by the motor and a transducer (transducer) which converts a rotational movement (R) from the shaft 401 into a linear movement (D) of the carriage in the drive direction. In the example of fig. 4, the transducer comprises a gear 400, the gear 400 having teeth complementary to a set of teeth in the rack 50 provided as a carriage guide, thereby providing a rack and pinion assembly.

The foregoing description has been presented to illustrate and describe certain examples. Examples of different groups have been described; these examples may be applied alone or in combination, sometimes with synergistic effects. This description is not intended to be exhaustive or to limit these principles to any precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is to be understood that any feature described in relation to any one example may be used alone, or in combination with other features described, and may also be used in combination with any feature of any other example, or any combination of any other examples.