KR100461700B1 - Safety razor blade unit, cartridge and shaving razor - Google Patents

Abstract

The safety razor blade unit of the present invention has a guide 2, a cap 3, and three parallel blades 11, 12, 13 mounted between the guide and the cap, and at least one of the above The blades, the guides and the caps may also be used to obtain a modified blade geometry such that the exposed portion of the first row blade 11 is not greater than zero and the exposed portion of the third row blade 13 is not less than zero. It is movable up to a non-shaved position for correction. At least one of the cap 2 and the guide 3 is a spring 20 to a non-shape position with an edge disposed below the plane where all the blades between the guide and the cap abut the skin contacting surfaces of the guide and the cap. Or move against the force of 21). The blades can be independently spring-loaded or supported for integral movement on a carrier pivotally mounted within the frame of the safety razor blade unit.

Description

Blade unit and shaving cartridge and safety razor comprising them {SAFETY RAZOR BLADE UNIT, CARTRIDGE AND SHAVING RAZOR}

TECHNICAL FIELD The present invention relates to a safety razor, and more particularly to a safety razor having a blade unit having a plurality of blades formed with sharp edges arranged in parallel so as to continuously pass through the skin subjected to shaving. The present invention can be used for safety razors having blade units permanently attached to the razor handles, and for safety razors having blade units detachably mounted to the handles so as to be replaceable when the blade edges have become dull. The blade unit is fixedly mounted to the handle, or is rotatably mounted about an axis parallel to the blade edge with respect to the handle by the force applied to the blade unit during shaving.

The present invention relates to a blade unit of a safety razor in which three blades and blade edges are arranged in a correlated manner. In conventional PCT / US94 / 10717, the blade edge has a specific structural shape, i.e., the first blade having an edge less than or equal to zero with the edge at the nearest edge of the guard, and the third blade with an edge at the nearest edge of the cap has a greater than zero exposure. The shaving performance was improved by the shape of the structure which has. The most effective arrangement of the arrangement is that the first blade has a negative exposure in the absolute range of 0 to 0.2 mm, preferably on the order of -0.04 mm for a first blade distance of approximately 0.7 mm, The blade has a dosage value of not greater than approximately +0.3 mm (preferably less than +0.2 mm), for example, +0.06 mm (or +0.09 mm), and the second blade has an exposure of approximately 0 The second and third blade distance is 1.0 to 2.0mm each, preferably about 1.5mm. For convenience, the arrangement of the structures described and claimed in the patent application is referred to herein as the "target geometry of the blade".

Blade exposure refers to the measured vertical distance or height of the blade edge with respect to the plane in contact with the skin contact surface of the blade unit element which follows before and after the blade edge. The blade exposure is a positive number if the blade edge is above the contact surface, ie closer to the skin surface to be shaved than the contact surface, and if the blade edge is below the contact surface, ie away from the skin than the contact surface. If it is, it is a negative number. The span of the blade is the distance from the blade edge to the skin contact element immediately before that edge, as measured along the tangent and tangential line extending between the skin contact element and the blade edge.

The structure of the three blades described above is applicable to a blade unit in which the blade is mounted relatively in relative motion with the guard and the cap. Such a blade structure is also applicable to a shaving initiation structure or the initial or rest geometry in the case of a blade unit in which the blade is deformed under the force applied to the blade during shaving by mounting a spring on the blade.

Figure 1 shows a preferred blade shape during shaving and corresponds to Figure 2 of the accompanying drawings of conventional PCT / US94 / 10717.

Figure 2 shows a cross-sectional view of a first embodiment of the present invention in non-use.

3 is a view of the blade unit of FIG. 2 with portions occupying relatively different positions.

4 and 5 are diagrams of a second embodiment of the present invention corresponding to FIGS. 2 and 3;

6 and 7 are diagrams of a third embodiment of the present invention corresponding to FIGS. 2 and 3.

8 to 10 show different directions of the cartridge relative to the skin of the shaver.

11 is a cross sectional view of an additional embodiment showing the use of a cantilever arm for spring mounting the blade.

The present invention allows a portion of the blade unit to accommodate the desired operation of the other portion without losing the advantages of the blade structure described above. Accordingly, in accordance with a preferred embodiment of the present invention, there is provided a safety razor blade unit comprising a first blade to a third blade having a guard, a cap, and parallel sharp edges disposed successively between the guard and the cap. One or more elements selected from the blades, guards, and caps are non-shaved to change the blade dosage of the blade unit to achieve a modified blade structure in which the exposure of the first blade is not greater than zero and the exposure of the third blade is not less than zero. Removable from position, one or more blades of the first and third blades have different exposure doses when the one or more movable elements are in the non-shaved position.

At least one element is deflected slightly by means of a spring-like means at the start of shaving, ie in a non-shaving action position, that does not apply the target structure of the blade, but if the blade unit is applied to the skin during shaving, the at least one element Change the position to the position forming the target structure.

One or more elements include guards and / or caps and / or one or more blades.

According to another embodiment of the invention, the invention provides a safety razor blade unit comprising a guard, a cap and a plurality of blades with parallel sharp edges disposed successively between the guard and the cap, the guard and the cap In the non-shaved operating position, the pre-determined operating position constituting the quartz blade structure is movable against the spring force, and in the non-shaved operating position the blade edge is below the surface in contact with the skin contact of the guard and the cap. Is placed on.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention will be more clearly understood from the following description with reference to the accompanying drawings.

FIG. 1 is a schematic illustration of a safety razor blade unit with a frame 1 forming a guard 2 and a cap 3 and equipped with a lubrication strip 4. The supporting member includes a first blade 11, a second blade 12, and a third blade 13, and the blades having edges are located in the common plane P. The shape of the blade unit is as follows.

a) the distance S ₁ of the first blade 11 is 0.5-1.5 mm, preferably 0.7 mm;

b) a second distance of the blade (12) (S ₂₎ and a third distance of the blade (13) (S ₃₎ is in the range 1.0-2.0mm, respectively, and preferably 1.5mm;

c) the distance S ₄ from the edge of the third blade to the cap is approximately 1.80 mm;

d) the dosage of the first blade is -0.04 mm;

e) The exposure of the second blade 12 is not less than the exposure amount of the first blade 11 and not greater than the exposure amount of the third blade 13, and in this embodiment is approximately 0 as shown. ;

f) The exposure of the third blade is about +0.09 mm.

The embodiments of the present invention described below are arranged to achieve a generally similar blade structure, although the above structure does not apply when the blade unit is in the idle state and in non-use.

In the blade unit of the first embodiment shown in FIGS. 2 and 3, the guard 2 slides up and down between the upper and lower end positions formed by the stop surfaces 31, 37 provided in the frame 1. It is mounted on the frame for the purpose of operation. The guard is slightly pressed into the upper end position by the spring 20. Similarly, the cap 3 is slidably mounted by the frame for the purpose of vertical movement between the end positions formed by the stop surfaces 35, 38, and the spring 21 slightly slides the cap into the upper end position. Bias. In the upper end position of the guard, the upward facing shoulder 30 of the guard abuts the stop face 31 formed on the flange 32 integrally formed with the frame, as can be seen in FIG. Similarly, in the upper end position of the cap, the upward facing shoulder 34 of the cap abuts the stop surface 35 formed on the flange 36 formed integrally with the frame. In the lower end positions of the guard and the cap, the guard and the cap respectively abut the stop surfaces 37 and 38 formed on the bottom wall of the frame, as shown in FIG. The three blades 11, 12, 13 are mounted stationarily on the frame or are biased by individual springs against the stop face 18 formed in an inverted flange on the end wall of the frame. In non-use the blade structure does not achieve the target structure of the blade. The negative exposure of the first blade has an absolute value greater than 0.2 mm and the third blade has a negative exposure value. In use, the guard and the cap have an improved construction that generally corresponds to that of FIG. 1, and are forced against the springs 20, 21 that act individually, as shown in FIG. . With this target structure, the blades deflect downward against each spring 19, but do not lose the improved shaving performance due to the target structure. Moreover, the guard and cap come into contact with the skin when using the blade unit such that the guard and cap operate under the influence of separate springs 20 and 21, respectively, so that the guard and cap maintain their lower end position.

In the second embodiment of Figs. 4 and 5, the cap 3 and the guard 2 are fixed to the frame as shown in Fig. 1, but the blades are subjected to the inverted action of the respective springs 24, Will be affected. The spring must press the blade slightly upwards against the static surface (as mentioned in connection with FIGS. 2 and 3) but with the idle state of the blade unit without the preload on the blade as shown. -The spring does not apply pressure when in use. In the state of such a blade unit, the target structure suitable for the blade is not stable, for example, since the first blade has a positive exposure value and the exposure amount of the third blade is larger than +0.2 mm at most. In use, the blade is pressed against the spring force, so that an improved structure is achieved, as shown in FIG. 5, resulting in the target structure of FIG. If necessary, the blades are provided with a stop to pre-determine where the deflection is necessary to achieve the target structure. Alternatively, it is possible to select a spring rate which allows the deflection from the position along the target structure to be not excessive.

6 and 7 also have a fixing guard 2 and a cap 3. The three blades 11, 12, 13 are rockers supported on the frame 1, such as by shell bearings, so that the blades pivot integrally about the pivot axis A located on the blade edge. It is mounted to the unit 26. The leaf springs 28 supported by the frame act on the rocker to force the springs slightly into the non-shaved position as shown in Figure 6, where the blades are out of their target structure, thereby providing a first blade 11. ) Has a positive exposure value, and the third blade 13 has a negative exposure value. In use, the rocker unit 26 is pivoted against the action of the spring 28 by the force applied, thereby securing it to a frame, such as a stop 40 or 41, schematically shown in the figure, as shown in FIG. The pre-determined position by the stop. In the state of such a blade unit, the structure is as described above with reference to Fig. 1, so that the target structure of the blade can be applied. As described above, the blade is fixedly mounted to the rocker, but with rocker mounting by the spring, during shaving, the blade will be biased from the target structure as described above in connection with FIGS. 2 and 3.

Although the parameters of the structure to obtain the best shaving performance are not satisfactory at the start of shaving, all embodiments can be adapted to be obtained using the parameters of the structure. Although some embodiments have been described, the invention is not limited thereto and may be practiced with other embodiments without departing from the scope of the claims. For example, only one of the guard and the cap may be movable, the blade and the guard and / or the cap may be movable, or only one or both of the blades may be movable. Other combinations of movable elements are also possible. The element may also select another way, such as arranging the guard to bend, tilt, and / or move to change the distance of the first blade, such as adjusting the blade exposure.

A feature of the movable elastomeric guard and / or cap, as in the embodiment of Figures 2 and 3, is that, in non-use, the blade edge is disposed both below and in contact with the skin contact surfaces of the guard and the cap. . The guard and / or cap are then easily repositioned to the retracted position formed by the stop to obtain the desired blade structure.

During shaving, if a cartridge with three elastic mounting blades exhibits a "forward force" pattern, that is, the force applied to the third blade is greater than the force applied to the first blade and the second blade If the applied force is in the middle of the force applied to the first and third blades or is subjected to the same force as the force applied to either the third or first blades, this results in a beneficial shaving result. The pattern of force on the blade is affected by the cartridge orientation bias effect, blade structure, and blade spring arrangement, as described below.

Cartridge direction deflection correlates to how the angular orientation of the cartridge with respect to the skin surface affects the force exerted on each blade. 8 to 10 show three cartridge directions, ie the neutral direction, the cap-heavy direction on the cap side, and the greater force on the guard side. In the figure, the cartridge 130, including the guard 132, the cap 134, and the blades 136, 138 and 140, shows the direction of the cartridge relative to the skin surface 142 before the skin surface is deformed. During shaving, the cartridge is generally pushed to the skin surface, deforming the skin surface so that the entire top of the cartridge is in contact with the skin. If the spring preload and the modulus of elasticity, which are optimal exposure conditions (non-shaving conditions) are the same for each blade, the cartridge direction controls the pattern of force applied to the blades during shaving.

8 shows that the cartridge 130 is in a neutral direction. In this case, the cartridge 130 is pressed against the skin surface 142 by the user so that all the blades are delivered to the shaving contact, exerting a uniform force on the three blades. To create a progressive force pattern, the blade structure and / or blade spring arrangement is adjusted as described below.

In Figure 9, cartridge 130 has a direction in which greater force is applied to the cap. In this case, the cap 134 is in contact with the fur surface at the start of shaving. As the remainder of the top of the cartridge is pushed against the skin, more force is applied to the blade close to the cap. Therefore, the force on the third blade is in the forward force pattern, and the force on the second blade is greater than the force on the first blade.

10 is a view showing that the cartridge 130 has a direction in which a greater force is applied to the guard side. In this case, the guard 132 is in contact with the skin at the start of shaving. As the remainder of the cartridge top is pushed against the skin, more force is applied to the blade close to the guard. Therefore, the force applied to the first blade is greater than the force applied to the second blade, which is larger than the force applied to the third blade. Thus, the state where a greater force is applied to the guard side increases to the opposite side of the "forward force". To generate the forward force pattern, the blade structure and / or blade spring arrangement is adjusted to prevent the pattern of force occurring in the other direction due to the greater force being applied to the guard side, as described below.

For cartridges that are not pivotally connected to the handle, the cartridge direction relative to the skin and thus the cartridge direction deflection is generally determined in the direction of the cartridge relative to the handle. For cartridges attached to handles via pivots that are added to the cartridge's orientation at rest, the pivot zone and spring return force affect the cartridge direction deflection. For example, if the cartridge orientation at rest is as shown in Figure 9, the cap contacts the skin at the start of shaving; If the pivot is in the guard area and there is a small spring return force, the cartridge will be in a state where more force is applied to the guard side during shaving.

As mentioned above, the pattern of force acting on the blade is also affected by the blade structure and the blade spring arrangement. The blade structure is based on exposure at rest. Blade spring arrangement is based on modulus and preload.

Figure 11 illustrates one way of providing elastic mounting for blades and how the exposure of the blades is adjusted at rest (other spring mounting methods may be used). With reference to Figure 11, a cantilever plastic arm ( 144 extends from the housing sidewall 146 and elastically supports the bending top outside at one end of the blade. The cutting edge 150 of the blade is prevented from being moved upwards by the metal clip 152 fixed to the housing. A similar arm extending from the other side of the cartridge elastically supports the other end of the blade under a similar retaining clip. Paired arms 144 correspond to springs 19 and 24 shown in FIGS. The upward force F exerted on the blade 148 by the arm 144 acting as a cantilever beam is a linear function of y that is shifted downward from its unbiased position. That is, F = k * y, where k is a spring constant that depends on the length of the arm (L), the moment of inertia (I) of the arm, and the elastic modulus (E) (k = L ³ / (3EI)). If (when that is, the arm 144 k * y pre-load force (F _P in _P) is provided) the arm 144 is by reulrip 152 at the time of making the distance (y _p), by deflecting If, wherein R y is equal to y _p + y _d , where y _d is equal to the downward working distance in the rest position shown in FIG.

The force applied to the blade can be controlled in a variety of ways to produce a forward force pattern during shaving. That is, the arm 144 may be modified in length or inertial motion (eg, to provide a thick cross section to the arm 144) to provide another spring constant. In addition, in the arm 144, an area in which the arm 144 is attached to the housing sidewall 146 in the upward direction (increase of preload force) or downward (reduction of preload force) while maintaining the same arm cross section and length. Can be moved to provide another preload force F _P. The position or shape of the clip 152 can also be adjusted in relation to the arm to adjust the preload force F _P. For example, the clip 152 may be mounted lower or higher than one blade contact portion is in contact with the other blade.

One way to achieve a forward force pattern during shaving is to have progressive exposure and the same preload force for all blades and spring constants at the start of shaving. Another way to achieve a forward pattern during shaving is to have an exposure (eg all zero) and a gradual preload at the same shaving start. The gradual preload is provided with a spring constant for the third blade that is greater than the spring constant for the second blade, and with a spring constant for the first blade that is less than the spring constant for the second blade. Progressive preloading is also achieved with a second arm mounted larger than the first blade and a third arm mounted larger than the second blade, but using the same arm (eg, the same spring constant) for all blades. Can be.

Exposure at spring, preload, and shaving initiation is used in combination with cartridge direction deflection to create a progressive exposure and / or forward force pattern. For example, if the cartridge has a gradual structure with a guard-weight direction (e.g., via a weak spring return force with a pivot portion adjacent to the guard as described above), The transition to higher preloads, spring constants, and exposure doses at rest and in the third and second blades than in one blade. Other combinations used to improve forward forces during shaving include higher preloads, spring constants, or dosages at rest on the third blade than on the first blade, or a combination of these parameters with the first blade. In contrast, it includes having a larger value in the third blade. Preferably, the second blade has a value that is equal to the third blade to have an intermediate value or to advance the forward force pattern.

Spring preloads are generally in the range of approximately 25 g or less. The force acting on each blade can be expected to receive a force in the range of approximately 0-40 g, with a force of 0-20 gms in the first blade and a force of 0-40 gms in the third blade. The force acting on each blade is generally greater than 5 gm. The dosage at rest and the dosage during shaving are generally in the range described above.

Claims (60)

A safety razor blade unit comprising a guard (2), a cap (3) and first to third blades (11, 12, 13) with parallel sharp edges disposed successively between the guard and the cap; By changing the exposure value of the blade unit, three blades, guards and caps are selected so that a modified blade structure is achieved in which the exposure value of the first blade 11 is not greater than zero and the exposure value of the third blade 13 is not less than zero. At least one element is movable by a spring means from a non-shaving position that the blade unit occupies at rest and non-use, wherein the first and third when the at least one movable element is in the non-shaving position. Safety razor blade unit, characterized in that at least one of the blades has a different exposure value. The safety razor blade unit of claim 1, wherein the one or more elements are movable from the non-shaving position to a pre-determined position defined by the stop means or the pressing arrangement.  3. The safety razor blade unit of claim 2, wherein the at least one movable element is biased by spring means to an end position formed by a stop face (31, 35, 37, 38). 4. The safety razor blade unit of claim 3, wherein the at least one movable element comprises a guard. 4. The safety razor blade unit of claim 3, wherein the at least one movable element comprises a cap. 4. The safety razor blade unit of claim 3, wherein the one or more movable elements comprise one or more blades. 7. The safety razor blade unit of claim 6, wherein the blades are movable independently of each other. 7. The safety razor blade unit of claim 6, wherein said blade is integrally movable. The safety razor blade unit of claim 8, wherein the blade is held by a pivoting member. 10. The safety razor blade unit of claim 9, wherein the pivot member pivots about an axis A positioned on the blade edge. A safety razor blade unit comprising a guard (2), a cap (3), and a plurality of blades (11, 12, 13) with sharp edges disposed in parallel between the guard and the cap; The guard and the cap move against the spring force from the non-shaving position to the pre-determined operating position of the crystal blade structure, and return to the non-shaving operating position by the spring force; In a non-shaving position, the blade edge is disposed below a surface in contact with the skin contact surface of the guard and the cap. The safety razor blade unit according to claim 10, wherein in the quartz blade structure, the exposure amount of the first blade has a negative exposure amount in the range of 0 to 0.2 mm as an absolute value. 13. The safety razor blade unit of claim 12, wherein in the modified blade structure, the distance between the first blade and the guard is in the range of 0.5 mm to 1.5 mm. The safety razor blade unit according to claim 13, wherein in the quartz blade structure, the exposure amount of the third blade has a positive value not greater than +0.3 mm. 15. The safety razor blade unit of claim 14, wherein in the modified blade structure, the distance between the edge of the third blade and the edge of the second blade is in the range of 1.0 to 2.0 mm. 16. The safety razor blade unit of claim 15, wherein in the quartz blade structure, the distance between the edge of the second blade and the edge of the first blade is in the range of 1.0 to 2.0 mm. 17. The safety razor blade unit of claim 16, wherein in the modified blade structure, the second blade has an exposure amount that is not less than an exposure amount of the first blade and not greater than an exposure amount of the third blade. 18. The safety razor blade unit of claim 17, wherein in the modified blade structure, the exposure amount of the second blade is approximately zero. 20. The safety razor blade unit of claim 18, wherein in the modified blade structure, the exposure amount of the third blade has a positive value equal to the negative value of the exposure amount of the first blade. 20. The method of claim 19, wherein in the modified blade structure, the distance between the first blade edge and the guard is less than the distance between the first blade edge and the second blade and teeth and the distance between the second blade edge and the third blade edge. A safety razor blade unit. 21. The razor blade unit of claim 20, wherein in the quartz blade structure, the distance between the first blade edge and the guard is 0.7 mm. A housing having a connection structure for detachable connection to the handle, a guard (2) located at the front of the cartridge, a cap (3) located at the rear of the cartridge, and a housing positioned successively to the housing between the guard and the cap A shaving cartridge comprising first to third blades (11, 12, 13) with parallel sharp edges mounted independently for elastic-biased movement; The blade is characterized in that the blade is movable from the non-shaving position to a shaving position in which the force applied to the first blade (11) is less than the force applied to the third blade (13). 23. The method of claim 22, wherein in the shaving position, the force applied to the first blade is less than or equal to the force applied to the second blade, and the force applied to the second blade is less than the force applied to the third blade. A shaving cartridge characterized in that it is small or identical. 23. The shaving cartridge of claim 22, wherein the housing has a pivoting configuration that provides pivoting of the housing about a pivot axis. 25. The shaving cartridge of claim 24, wherein the pivot axis is in front of the blade in the region of the guard. 23. The shaving cartridge of claim 22, wherein the cartridge is applied with a greater force on the guard side. 27. The shaving cartridge of claim 25, wherein the cartridge is applied with a greater force on the guard side. The handle, the housing connected to the handle, a guard (2) located in front of the housing, a cap (3) located behind the housing, and a resilient-biased movement relative to the housing that is continuously positioned in the housing between the guard and the cap. A razor comprising first to third blades (11, 12, 13) having parallel sharp edges that are independently mounted; The blade is characterized in that the blade is moved from the non-shaving position to a shaving position in which the force applied to the first blade (11) is less than the force applied to the third blade (13). 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the third blade has a greater spring constant than the first blade. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the third blade has a greater preload than the first blade. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the third blade has a greater exposure dose than the first blade when at rest. 28. The shaving cartridge of claim 23, 26 or 27, wherein said second and third blades have a greater spring constant than said first blade. 28. The shaving cartridge of claim 23, 26 or 27, wherein said second and third blades have a greater preload than said first blade. 28. The shaving cartridge of any one of claims 23, 26, or 27, wherein the second and third blades have a greater exposure amount at rest than the first blade. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the third blade has a greater exposure amount and preload at rest than the first blade. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the third blade has a greater exposure dose and a spring constant at rest than the first blade. 28. The shaving cartridge of any one of claims 23, 26 or 27, wherein the third blade has a preload and a spring constant greater than the first blade. 28. The method of any one of claims 22, 26, or 27, wherein the second and third blades have a larger exposure dose, preload and spring constant than the first blade. Shaving cartridges. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the second and third blades have a greater exposure and preload at rest than the first blade. 28. The shaving cartridge of any one of claims 22, 26, or 27, wherein the second and third blades have a greater exposure dose and spring constant at rest than the first blades. 28. The shaving cartridge of any one of claims 22, 23, 26 or 27, wherein the second and third blades have a greater preload and spring constant than the first blade. . 28. The method of any one of claims 22, 23, 26 or 27, wherein the second and third blades have a greater dose at rest, preload, and spring constant than the first blades. Featuring a shaving cartridge. 28. The force applied to any one of claims 22, 23, 26 or 27 wherein the force applied to the first blade during shaving is between 0 and 20 gms and the force applied to the third blade during shaving. Shaving cartridge, characterized in that greater than 0 and less than 4 Ogms. A housing of the connection configuration detachably mounted to the handle, a guard (2) in front of the cartridge, a cap (3) at the rear of the cartridge, and between the guard and the cap, continuously arranged parallel to the housing and elastically biased relative to the housing A shaving cartridge comprising first to third blades (11, 12, 13) having sharp edges independently mounted for operation; The blade is characterized in that the cartridge is moved from the non-shaving operating position occupied by the cartridge at rest and non-use to a shaving position in which the exposure of the first blade 11 is less than the exposure of the third blade 13. Shaving cartridges. 45. The shaving of claim 44, wherein in the shaving position, the exposure of the first blade is less than or equal to the exposure of the second blade, and the exposure of the second blade is less than or equal to the exposure of the third blade. Cartridge. 29. The razor of claim 28, wherein said third blade has a greater spring constant than said first blade. 30. The razor of claim 28, wherein said third blade has a greater preload than said first blade. 29. The razor of claim 28, wherein said third blade has a greater exposure than said first blade when at rest. 29. The razor of claim 28, wherein said second and third blades have a greater spring constant than said first blade. 29. The razor of claim 28, wherein said second and third blades have a greater preload than said first blade. 29. The razor of claim 28, wherein said second and third blades have a greater exposure amount than said first blade when at rest. 29. The razor of claim 28, wherein said third blade has a greater exposure amount and a preload at rest than said first blade. 29. The razor of claim 28, wherein said third blade has a greater exposure amount and a spring constant at rest than said first blade. 29. The razor of claim 28, wherein said third blade has a greater preload and a spring constant than said first blade. 29. The razor of claim 28, wherein said third blade has a greater exposure amount at rest and a preload and a spring constant than said first blade. 29. The razor of claim 28, wherein the second and third blades have a greater exposure amount and a preload at rest than the first blades. 29. The razor of claim 28, wherein said second and third blades have a greater exposure amount and spring constant at rest than said first blade. 29. The razor of claim 28, wherein said second and third blades have a greater preload and spring constant than said first blade. 29. The shaving razor of claim 28, wherein the second and third blades have a greater exposure amount at rest, a preload, and a spring constant than the first blades. 29. The razor of claim 28 wherein the force applied to the first blade during shaving is between 0 and 20 gms and the force applied to the third blade during shaving is greater than 0 and less than 40 gms.