The present invention relates to a paintball loader for a paintball marker (or paintball gun) including a paintball storage compartment for holding a supply of paintballs, an outlet through which a paintball may pass in a feeding direction into a paintball marker on which the loader is mounted, a frame for supporting a paintball feeding arrangement for actively feeding paintballs in the compartment through the outlet, the feeding arrangement having one or several points of entry for receiving a paintball, wherein a surface of the frame has such a form that, when the paintball loader is held in an upright position, the surface slopes towards the points of entry.
A paintball marker uses compressed gas, such as air or nitrogen, to propel spherical projectiles including a colored liquid enclosed in a fragile gelatin casing. The projectiles are called paintballs, and they were originally used e.g. to mark objects, hence the name paintball marker.
Today, paintball markers are widely used for target practice and in mock war games, where participants try to “mark” members of another team to send them of the game field. In such games, it is critical to have markers with high capacity (many balls), rapid firing and satisfactory reliability (no jamming balls, etc).
A paintball marker is normally provided with a paintball loader mounted on the upper side of the marker. The loader is essentially a container for holding a supply of paintballs to be loaded into the marker. The balls are fed through an outlet into the marker, where they are pushed through the barrel of the marker by means of e.g. compressed air. In many paintball loaders, the paintballs are simply pulled by gravity through the outlet. More sophisticated loaders, however, typically employ some kind of battery powered feeding arrangement, which uses force to feed the paintballs through the outlet and into the marker. Such a mechanism increases the firing rate and reduces the risk of paintball jam. The feeding arrangement also ensures that the marker can be used also when not held in an upright position.
In later years, significant efforts have been made to improve the performance of paintball markers and in particular the paintball loaders. Such improvements include various types of feeding arrangements, see e.g. U.S. Pat. No. 8,950,386 to the present inventor.
Another area subject to improvement is the holding capacity of the loader, i.e. the number of paintballs it can hold. For example, document US 2012/103316 shows a paintball loader including a ramp member which is pivotable between two positions. In a first, lowered position, the ramp is depressed to increase the free volume of the loader, so as to hold a maximum number of balls. In a second, raised position, the ramp is elevated to form a ramp sloping in the direction of the feeding arrangement.
However, the force required to depress the ramp in US 2012/103316 is significantly weaker at the end of the ramp furthest away from the pivoting edge, and significantly stronger closer to the edge. This provides an unsatisfactory pressure distribution and function, Also, the ramp in US 2012/103316 provides rather limited additional storage. It would be desirable to even further increase the holding capacity of paintball loaders.
It is an object of the present invention to further improve the holding capacity of paintball loaders.
According to the present invention, this object is achieved by a paintball loader of the type mentioned by way of introduction, including a supporting plate, having a front end facing the a firing direction, and a rear end opposite the front end, at least two abutments, and a suspension member having one end operatively connected to a central region of the supporting plate and a second end operatively connected to the frame, the suspension member being spring loaded to press the supporting plate against the abutments in a direction substantially opposite the feeding direction. The supporting plate is depressable against a force of said spring loaded suspension member, for moving the supporting plate in the feeding direction from a first position, in which the supporting plate is pressed against the abutments and serves to guide paintballs in the compartment towards the points of entry, to a second, depressed position.
By “front” and “rear” is here intended to indicate towards a front end and towards a rear end, respectively, of a paintball marker on which the loader is mounted. As indicated above, the “front” will be facing the intended firing direction, i.e. the direction in which paintballs will be discharged by a paintball marker on which the loader is mounted.
The design according to the present invention, with a spring loaded suspension member arranged between the plate and the frame, allows all parts of the plate to be resiliently moved in the feeding direction. The available volume for receiving and holding paintballs can thus be increased by depressing the supporting plate. Thereby, more paintballs can be held in the paintball loader. As a representative example, an additional ten paintballs can be held.
Conventionally, the entire volume for holding paintballs is located above the point of entry of the feeding arrangement when the marker is in its upright position, so that balls can roll or fall into the feeding arrangement. According to the present invention, the entire supporting surface is depressable. This makes additional space available below the upper surface of the feeding arrangement, where normally the paintballs would risk getting stuck. According to the invention, however, the biasing member will press the supporting plate into contact with the abutment surfaces and back into its first position. The abutment surfaces can be configured so that any paintballs resting on the supporting plate in its first position easily can find their way into the feeding arrangement.
In one embodiment, the supporting plate is, in the second position, moved completely beyond the points of entry in said feeding direction, i.e. below the openings of the feeding arrangement when the loader is in its upright position.
The suspension member will transfer to spring loading to the central region of the plate, such that the force required to depress the plate can be more evenly distributed. It should be noted that the exact distribution of force required to depress the plate will be determined by the location of the connection between the plate and the suspension member, as well as the location of any abutments between the plate and the suspension member.
According to a preferred embodiment, the first end of said suspension member is connected to the plate so as to be rotatable around a first axis. This enables the plate to be depressed in any orientation, while transferring motion to the suspension member.
Similarly, the second end of said suspension member can be connected to the frame so as to be rotatable around a second axis, parallel to the first axis. The suspension will thus act as a fulcrum lever, so that a large movement of the plate close to the first axis will result in a small movement close to the second axis.
The suspension member can be spring loaded by at least one biasing element (such as a coil spring) provided between the frame and said suspension member. Preferably, such biasing element(s) is/are arranged relatively closer to the second axis than the first axis. In this way, the action of the biasing elements can make use of the fulcrum effect.
The abutments may include a front abutment formed in the frame and arranged to abut a front portion of the plate. Such an abutment will have the effect that when the plate is subject to a pressing force (in the feeding direction) rear of the first axis, the plate will rotate around the first axis. The front end of the plate will then be pressed against the front abutment, while the central region will be pressed against the suspension member, and force the suspension member to rotate against the spring loading.
The abutments may further include a central abutment formed in the first end of the suspension member and arranged to abut an underside of the plate in a point located between the first abutment and the first axis (C). Such an abutment will have the effect that when the plate is subject to a force in front of the first axis, the plate will be pressed against the central abutment and force the suspension member to rotate against the spring loading.
The abutments may also include a rear abutment formed in the frame and arranged to abut a rear portion of the plate. Such a rear abutment may substitute the central abutment. In that case, a force acting in front of the first axis will have a similar effect as a force acting rear of the first axis as was described above. However, such a rear abutment may also be provided onlyl for alignment purposes, to ensure that the rear edge of the plate is in a desired position with respect to the entry points of the feeding arrangement.
According to one embodiment, the suspension member is generally V-shaped, with two legs which are joined in the first end of the suspension member and separated in the second end of the suspension member. The suspension member will thus have two points of connection with the frame, preventing any rotation around an axis perpendicular to the first and second axis. At the same time, the single point (or at least limited area) of contact between the suspension member and the plate may allow for at least limited rotation of the plate around an axis perpendicular to the first and second axis. Such rotation may be beneficial in some applications.
The present invention will be described in more detail with reference to the appended drawings, showing currently preferred embodiments of the invention.
In the following description, currently preferred embodiments of the invention will be described with reference to a paintball marker held in its normal use, upright position. Any relationship or direction such as front, rear, above, bottom, upwards, etc, are thus to be understood as referring to a loader in this position.
With reference to
Inside the housing 110 is a frame 114, sandwiched between the upper and lower parts 110a, 110b. The frame 114 is configured to house a paintball feeding arrangement, including a rotating member 115 and an electric motor 116, connected by suitable gears to rotate the rotating member. The rotating member has a plurality of wings 117, and cavities 118 formed between the wings 117. When the rotating member is rotated by the motor, paintballs in the cavities 118 will be pushed by the wings through the outlet 107 in a ball feeding direction A. The cavities thus form the points of entry into the feeding arrangement.
Between the frame 114 and the upper portion of the housing 110a is formed a compartment 119 for storing paintballs. The surface of the frame 114 surrounding the feeding arrangement is formed such that when the loader is in an upright position, paintballs will be forced by gravity into the cavities 118 of the rotating member 115.
In front of the feeding arrangement, as seen in the firing direction B of the marker, is an essentially flat supporting plate 120 suspended by a suspension member 121. The suspension member is here a V-shaped link, with the pointed front end of the V connected to the plate 120, and the two legs connected to the underside of the frame 114. The front end is connected to the plate 120 so as to be rotatable around an axis C, essentially perpendicular to the firing direction. In the illustrated example, the front end is formed with two protrusions 123, which are rotatably received by two holders 124. The legs of the V-shaped suspension member 121 are each connected to the frame so as to be rotatable around a common axis D, also essentially perpendicular to the firing direction. For example, the legs may each have a protruding pin, which is received by a corresponding hole in the frame. Two biasing elements, here in the form of coil springs 122a, 122b, are provided to act between the arms of the V-shaped suspension member 121 and the frame 114, to spring load the suspension member around the axis D, and to thereby press the front end of the suspension member 121, and thus the plate 120, upwards, substantially opposite to the feeding direction A.
With particular reference to
It should be noted that with this design, the suspension member will always be pressed downwards when the plate is depressed. If the front of the plate is depressed (i.e. in front of the axis C), the plate will abut the tip 128 and the plate 120 and the suspension member 121 will rotate together around the axis D. If the rear of the plate is depressed (i.e. behind the axis C) the plate 120 will rotate around the axis C, but the protrusion 125 will abut the abutment 126 thus forcing the connection point between the plate 120 and the suspension member 121 downwards.
The plate 120 is depressable against the biasing force of the suspension member 121 into a second, lowered position, shown in
The effect of the two different positions of the plate 120 is more clearly shown in
The person skilled in the art realizes that the present invention by no means is limited to the preferred embodiments described above. On the contrary, many modifications and variations are possible within the scope of the appended claims.
For example, the supporting plate may be positioned behind the feeding arrangement instead of in front of the feeding arrangement. Further, the frame 114, which here has been described as a separate part, can alternatively be integrated with the lower housing portion 110b. The design of the suspension member 121 may also be different, and a H-shape could be an alternative to the V-shape. A H-shaped suspension member 121 would prevent any rotation of the plate 120 with respect to the frame 114.
Number | Date | Country | Kind |
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15156379 | Feb 2015 | EP | regional |
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Number | Date | Country | |
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20160245614 A1 | Aug 2016 | US |