CUTTING HAND TOOL WITH PRESSURE INDICATION

Abstract

A cutting hand tool with a pressure indicating means with a sensor which is actuated when the cutting edge is forced onto a material, a processing means receiving a signal from said sensor and sending a signal to a notification means indicating the pressure as soon as a predefined condition is met.

Claims

1. A cutting hand tool comprising a housing, a cutting blade having at least one cutting edge and a pressure indicating means consisting of a sensor, a processing means connected to said sensor and a notification means connected to said processing means wherein said sensor is actuated when said cutting edge is forced onto a material to cut and said processing means receives a signal from said sensor and sends a signal to said notification means as soon as a predefined condition is met.

2. The cutting hand tool of claim 1 wherein said sensor is a pressure sensor, said blade is connected to the cutting hand tool in a manner allowing a small movement of the blade when said cutting edge is forced onto the material to cut and said pressure sensor is actuated when said movement occurs.

3. The cutting hand tool of claim 1 wherein said sensor is a strain sensor, said blade undergoes a deformation when said cutting edge is forced onto the material to cut and said strain sensor is actuated when said deformation occurs.

4. The cutting hand tool of claim 1 wherein said notification means provides a visual or acoustic or tactile or electromagnetic signal related to the pressure being applied to said cutting edge of the blade.

5. The cutting hand tool of claim 4 wherein said visual signal provided by the notification means is shown on a display.

6. The cutting hand tool of claim 4 wherein said visual signal provided by the notification means consists of a plurality of lights showing the amount of pressure applied by lighting additional lights with increasing pressure.

7. The cutting hand tool of claim 4 wherein said visual signal provided by the notification means consists of one or several lights showing different colors depending on the amount of pressure applied.

8. The cutting hand tool of claim 7 wherein said lights use the colors green, yellow and red.

9. The cutting hand tool of claim 4 wherein said acoustic signal is emitted by the notification means when the pressure applied on said cutting edge of the blade reaches a predefined level.

10. The cutting hand tool of claim 4 wherein said acoustic signal increases in volume if the pressure applied on said cutting edge is increased beyond a predefined level.

11. The cutting hand tool of claim 4 wherein said tactile signal is emitted by said notification means in form of an impulse or vibrations when the pressure applied on said cutting edge of the blade reaches a predefined level.

12. The cutting hand tool of claim 4 wherein said notification means emits the electromagnetic signal by using any common wireless communication technology, thus allowing it to be received a readout device.

13. The cutting hand tool of claim 12 wherein said electromagnetic signal includes an identification of the cutting handtool, allowing any receiving device to identify different cutting hand tools.

14. The cutting hand tool of claim 2 wherein said movement is a pivoting movement, or any other type of displacement.

15. The cutting hand tool of claim 2 wherein said sensor is a pressure sensor consisting of a piezoelectric or potentiometric or capacitive sensor or another usual type of sensor.

16. The cutting hand tool of claim 2 wherein said sensor is an electrical contact.

17. The cutting hand tool of claim 2 wherein said sensor is a pressure switch.

18. The cutting hand tool of claim 3 wherein said sensor is a strain gauge.

19. The cutting hand tool of claim 1 wherein the energy needed for the operation of said sensor and said processing means is supplied by a power source located in said housing.

20. The cutting hand tool of claim 21 wherein said power source is a battery or another commonly used type of accumulator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] In the drawings:

[0009] FIG. 1: Side view of the cutting hand tool

[0010] FIG. 2a: Top view of the cutting hand tool where the notification means are lights

[0011] FIG. 2b: Top view of the cutting hand tool where the notification means is a display

[0012] FIG. 2c: Cutting hand tool where the notification means is a sound source

[0013] FIG. 2d: Cutting hand tool where the notification means produces vibrations

[0014] FIG. 2e: Cutting hand tool where the notification means emits an electromagnetic signal

[0015] FIG. 3: Cutting hand tool with a movable blade and a pressure sensor

[0016] FIG. 4: Cutting hand tool with a fixed blade and a strain gauge

[0017] FIG. 5: Cutting hand tool with blade guard

DETAILED DESCRIPTION OF THE INVENTION

[0018] A preferred embodiment of a cutting tool with pressure indication is described according to the drawings. This preferred embodiment is to be understood as an exemplary embodiment and any detailed description shall not be interpreted as limiting. Alternate embodiments obvious to one skilled in the art will not be described in detail or will be omitted to prevent the relevant details of the invention to be overlooked.

[0019] FIG. 1 shows that the proximal part of the housing 1 has an elongated handle-like shape suitable for gripping with the hand. The blade 2 protrudes out of the distal end of the knife and its lower edge 21 is the cutting edge. During the operation of the knife, the user grips the proximal part of the housing 1 and exerts pressure on the object to be cut via the cutting edge 21. This pressure is measured with a sensor 3 and the pressure information is processed by a processing means 4. Then, a notification means 41 provides a feedback to the user about the pressure applied on the cutting edge 21.

[0020] Any type of notification means 41 may be used, as long as the signal it emits can be noticed by the user and is related to the force he is applying to the knife.

[0021] The notification means 41 may be a visual indicator 41a, comprising lights or a display as shown in FIGS. 2a and 2b. The location of visual indicators 41a should be chosen in order to enable their visibility by the user, usually at the top of the distal part of the knife, as shown in FIGS. 1, 2a and 2b. In cases where a quantitative monitoring is desired, the exact value of the pressure can be shown on a display (FIG. 2b). Various types of displays can be used, e.g. LCD or LED displays. Alternatively, qualitative information on the pressure applied to the tool may be displayed by lighting different numbers of lights or lights of different colors (FIG. 1 and FIG. 2a).

[0022] The housing 1 may also contain a sound source 41b like a buzzer or bell (FIG. 2c) or a vibrating means 41c such as a vibration motor (FIG. 2d). For the comfort of the user, vibrations or sounds should only be generated if the pressure exceeds a certain threshold. However, these acoustic and tactile notification means 41b, 41c could also be implemented to increase in volume with increasing pressure beyond a certain threshold. This can force the user to immediately stop the activity due to the discomfort created.

[0023] A further possibility is the transmission of the pressure information wirelessly to a readout device 6 such as a display or a smartphone (FIG. 2e). This transmission may be a simple RF signal or use various other technologies like Bluetooth or NFC. Several knives may be connected to the same readout device 6, thus allowing a centralized monitoring of the operation of several tools. In such an implementation, it is important that the signal emitted by each knife is distinct from the others in order to be able to identify them. For example, the signal may contain a unique number for each knife. The readout device 6 may be located in the manager's office or by the maintenance division. In this embodiment, the cutting tool could automatically notify the maintenance division that the blade is dull and needs to be replaced. Likewise, the production line manager could detect incorrect uses of the knife, e.g. a user exerting an excessive force that could lead to RSI (Repetitive Strain Injuries) or non-conform cuts due to careless operation of the user. This monitoring may also serve quality management purposes: by monitoring the lifetime of the blades, the manager may identify defective blade batches or variations in quality between different blade suppliers.

[0024] In a more complex embodiment a combination of one or more of the notification means described above, especially a combination of a local notification means on the cutting hand tool and a wireless transmission of the pressure information.

[0025] There are several ways to detect the force applied on the blade by the user.

[0026] In one embodiment, the blade 2 can be movably attached to the housing 1, in a manner allowing a small movement of the cutting edge 21 when it is forced onto the material. FIG. 3 shows the example of a blade 2 which is pivotally fixed to the housing 1 around the pivot point 21. When the cutting edge 21 is forced onto the material, a force 81 is applied to the blade 2, which causes its rotation as shown by arrow 82 until it reaches the pressure sensor 3. So, the pressure sensor 3 is subjected to a force 83 proportional to the force 82 applied by the user on the blade 2. Potentiometric, capacitive, piezoelectric or any other common type of sensor 3 may be used.

[0027] In another embodiment shown FIG. 4, the force applied to the blade 2 can be directly measured on the blade 2 itself by monitoring its deformation with a strain gauge 3. In this embodiment the force exerted on the blade can be easily deducted from the value of the strain since these two values are proportional and the blade's strain/force proportionality coefficient can be found by a simple calibration procedure. The advantage of this option is that it doesn't require any movement of the blade 2, allowing the blade to be fastened firmly to the housing 1, which provides a better stability during the cut. Strain gauges 3 are cheap and easy to implement since they just need to be fixed to the surface of the blade 2.

[0028] In the presented invention, the sensor 3 interacts with a processing means 4 via a connection 42. This processing means 4 analyzes the signal delivered by the sensor 3 and activates the notification means 41 accordingly. In the case of a display 41a, the processing means 4 continuously converts the signal delivered by the sensor 3 into a force value and sends the information to the display 41a. In the case of a binary notification means indicating if the pressure is beyond a threshold value, the processing means 3 only compares the incoming signal to the predetermined threshold, and sends a signal to the notification means 41 if the threshold is reached or exceeded. In one embodiment where the notification means consists of a visual indicator 41a with three diodes, e.g. green, yellow and red, the green one is lit under a first threshold, the red one above a second threshold and the yellow one if the determined pressure value lies between these two values.

[0029] The energy required for the operation of the sensor 3, the processing means 4 and the notification means 41 is preferably supplied by a power source 6 located in the housing 1 of the knife. This power source can be a battery or any other common type of accumulator.

[0030] This description and the accompanying drawings show exemplary embodiments of the invention. The invention, however, should not be interpreted as being limited to these particular embodiments. Variations of the embodiments can be made by those skilled in the art without departing from the scope of this invention as defined by the claims.