Patent Description:
Traditionally the pricking the honeycombs by using spikes with the previously known devices is a very slow process, which process typically involves honeycomb frames are lifted up by a special lifting mechanism one by one from the loading rack and inserted into the pricking device, which then pricks the both sides of the honeycomb frames symmetrically. Typically, the spikes penetrate up to a couple of millimeter distance from the wax foundation, and the spikes cause movement to the honey. This effect, which causes movement to the honey inside the honeycombs, is especially important when honeycomb frames are filled with thixotropic honey, so that the viscosity of the honey is temporarily reduced and the honey can be extracted out from the honeycomb frame. Some major issues with the traditional pricking devices is that they are very expensive to purchase and their operating speed is so slow that some beekeepers need to purchase multiple traditional pricking devices so that the pricking process can keep up with the other honey extraction process.

Patent publication <CIT> discloses a therein comprised Cell opening mechanism, located on the base, being made on each side of the frame in as a set of elements of knives mounted in the same plane with the possibility of reciprocating movement in this plane along the surface of the honeycomb about axis. A knife has a limiter of the depth of cut, and the end of the knife has a serrated shape and protrudes along the front the edge of the limiter by <NUM>-<NUM>. The patent publication is in its closest nearness near the preamble of claim <NUM> so that the claimed embodiments differ essentially from the implementation in said publication.

The goal of this invention is a new kind of device for pricking honeycomb frames, which processes honeycomb frames remarkably faster and is more compact sized than previously known traditional pricking devices and also the new device is suitable for being equipped with traditional uncapping mechanisms, thus being remarkably more economical than previously known pricking devices.

A honeycomb frame wax cap pricking device according to the invention is defined by independent claim <NUM>.

The honeycomb frame wax cap pricking device according to an embodiment of the invention comprises a base frame, spike assemblies and a movement mechanism, in which case this movement mechanism is equipped with a rotating camshaft mechanism.

A honeycomb frame wax cap pricking device according to an embodiment of the invention comprises a chain mechanism for moving the honeycomb frames, which, according to one profitable embodiment of the invention, moves also the pricking mechanism. So, in this case one electric motor moves the honeycomb frames through the pricking device and the same electric motor also drives the pricking mechanism.

The perforation mechanism according to one profitable embodiment of the invention comprises essentially spike assemblies, perforation spikes and springs and also the movement mechanism that provides the rotational movement for the spike assemblies.

One such spike assembly comprises two base frame plates, the inner and outer base frame plates, which are connected to each other, and both of which are equipped with holes for the spikes. The inner base frame plate is located more near the honeycomb frame and the inner base frame plate is fastened for instance with using bolts to the outer base frame plate. Between the inner and outer base frame plates, there is a space for spikes so that other end of the spike is pushed through a positioning hole of the inner base frame plate up to a shoulder of the spike, and the other end of the spike is pushed to a positioning hole of the outer base frame plate. The spike stays in this position because the part of the spike, which is located inside the two base frame plates, is positioned inside a cross-sectionally circular compression spring. This compression spring pushes the shoulder of the spike towards the inner base frame plate, but the spike can move inside the hole of the inner base frame plate only up to the shoulder of the spike because the shoulder is larger than the hole diameter and thus cannot fit through the hole. The compression spring also cannot move out from the spike assembly through the hole of the outer base frame plate because the outer diameter of the spring is larger than the diameter of this hole. Because the inner and the outer base frame plates are fastened to each other, the spike assembly is held together while allowing the spike to move, if necessary, towards outer base frame plate all the way up to the maximum compression length of the spring.

In one profitable embodiment example of the invention, the pricking device is positioned underneath a set of traditional uncapping blades. Of course, the pricking device can be used also separately without the uncapping blades. In this embodiment example the opening and pricking of honeycomb cells can be carried out very fast because the honeycomb cells are pricked while the honeycomb frame is moving inside the device and does not require the honeycomb frame to be set stationary. By using this structure, it is possible to achieve uncapping and pricking speed of over twenty frames in a minute, which has been completely impossible by using other previously known pricking devices.

Also in this embodiment example of the invention, the mechanism, which produces motion for the pricking mechanism, is implemented by pivoting the spike assemblies with the help of slide bearings and connecting rod parts to rotating shafts, and the rotating shafts are connected to sprocket wheels which together form a camshaft mechanism. A transfer chain, which provides motion for the camshaft mechanism, is connected to the sprocket wheels as follows: A main shaft goes through the whole pricking device, into which main shaft are connected driving sprocket wheels on both outer sides of the base frame of the device, which sprocket wheels drive the pricking mechanism of the device. Also on both inner sides of the base frame of the device, driving sprocket wheels are connected to the main shaft for driving the frame transferring mechanism. This way implemented, only one electric motor drives both mechanisms while rotating one main shaft.

The rotational motion of the pricking mechanism is implemented in this same embodiment example so that the spike assemblies and the spikes move to the same direction as the honeycomb frame when the spikes perforate the honeycomb frame surface. This is implemented by connecting the rotation axes of each spike assembly to a transfer chain located outside the base frame of the device so that all the rotation axes, which are connected to same spike assembly, always have the same rotation direction. A spike assembly is pivoted to two rotation axes on both sides of the pricking device, so total amount of rotation axes for one spike assembly is four. The axes are aligned on top of each other in the same line vertically on both sides of the pricking device.

The frame transfer mechanism is connected so that a honeycomb frame moves between two uncapping blades, which are positioned symmetrically on both sides of the honeycomb frame, and right after the uncapping blades also the honeycomb frame moves between two spike assemblies, in other word, the honeycomb frame goes through the pricking mechanism, which is located underneath the uncapping blades. The pricking mechanism is also symmetric in respect to the passing honeycomb frame. So, the uncapping blades cut off the cappings symmetrically from both sides of the honeycomb frame, and after this the spikes, which are spring loaded and located in the spike assemblies, perforate inside the honeycombs symmetrically on both sides of the honeycomb frame.

Also in the same previously mentioned embodiment example, the spikes are positioned inside the base plates of the spike assemblies so that each spike is loaded by one spring. Each spring pushes each spike against that base plate of spike assembly, which is located more near the passing honeycomb frame. Then while loaded, the spike moves back, if the force pushing the spike is greater than the force created by the spring. This function prevents the spike from possibly breaking and also prevents any possible damage occurring to the honeycomb frame.

In the accompanied profitable embodiment examples of the invention, the distribution and quantity of spikes in the spike assemblies is the same as the distribution and quantity of honeycomb frame cells. This distribution and quantity of spikes could be different of course.

In one other embodiment example of the invention, the pricking mechanism is not connected to frame transfer mechanism. Instead, it is a separate mechanism located outside base frame of the device. For this embodiment example, it is profitable that the honeycomb frame is stationary while it is pricked, and also profitable is that the rotating movement of the pricking mechanism is positioned outside of the base frame of the device, and inside this base frame the spike assemblies move only in horizontal direction back and forth symmetrically in respect to the direction of motion of the through passing honeycomb frame. One remarkably profitable factor in this embodiment example is that in this case the device according to the invention can be built to be lower than in the case of the first embodiment example. For this embodiment example it is profitable, that the pricking mechanism is driven by its own separate electric motor.

As a special case, this second embodiment example can be implemented also so that the spike assemblies move also in addition to the horizontal direction, in the vertical direction. This way the resulting direction of movement is in an angle, but close to horizontally.

In the accompanied embodiment examples of the invention, the source of power for driving the mechanisms of the device according to the invention, is an electric motor, but based on the accompanied embodiment examples of the invention, it is clear that a device according to the invention can be implemented also to be pneumatic, hydraulic or for example the pricking mechanism could be driven by forces created by magnets, or possibly the pricking mechanism could be manually hand driven.

In the accompanied embodiment examples, the spike and the spring are separate parts, but they could be one part, in which case the part is rigid and shaped as a spike for the portion of the part which perforates the honeycomb, and is compressible for the portion of the part which is located inside the spike assembly. In this case, remarkably profitable is the savings in manufacturing costs when no separate spike is needed. To be taken into account is that in one device, there are thousands of spikes and also thousands of springs, for example in the devices shown in the accompanied embodiment examples, there are <NUM> spikes and therefore also <NUM> springs. Due to this structure, it is possible to pump out honey from the honeycombs through a center hole located in the center of the spring element. In this case, honey comes out in the end through the holes of the outer base frame plate of the spike assembly.

For the accompanied embodiment examples of the device according to the invention, it is profitable also that these are dimensioned so that the spikes of the pricking mechanism never contact the top and lower lists and side lists of the honeycomb frame, which reduces remarkably the risk of possible breakage of the spikes and thus makes the devices according to the invention remarkably more reliable to use than the previously known devices. Due to this fact, also the upper lists of the honeycomb frames possibly containing some nails does not have any effect on the functioning of the device according to the invention. Although the spikes, presented in the embodiment examples, never contact the lists of the honeycomb frame, this contact may occur if a honeycomb frame, which is shorter than the frame size for which that particular device was designed for, is inserted into the device according to the invention. That also is not a problem, because the spikes can move, if needed, towards the inside of the spike assemblies in the case some spikes happen to contact any of the lists of the honeycomb frame. In addition, the force pushing the honeycomb frame by each spike can be adjusted by changing the spring constant of the compression spring, which compression spring holds the spike in correct position. The material of the honeycomb frame does not affect in any way to the functioning of the device according to the invention. In addition, any nails possibly fastened to the lists of the honeycomb frame or the so-called Hoffmann extension of the honeycomb frame do not affect in any way to the functioning of the device according to the invention. Also, due to the spring loading of the spikes of the pricking mechanism, the different thicknesses of the lists of the honeycomb frames do not affect in any way to the functioning of the device.

The device according to the invention can be manufactured to be used in up-down direction, down-up direction or for example to be used in a side-to-side horizontal direction of the top list of the honeycomb frame or in a side list wise direction when the honeycomb frame is "tilted" horizontally.

A honey handling hardware configuration to form a honey processing system according to the invention, for example, for a honey extraction line or for an uncapping line, is defined by the subject-matter of claim <NUM> which comprises the honeycomb frame wax cap pricking device of claim <NUM>.

It must be said that a spike assembly according to the invention, inside which the springs are located and partially inside which are located the spikes, can be equipped with heating according to one embodiment example. For instance, a water heating piping located outside or inside the spike assembly or for instance an electrical heating resistance are suitable for heating elements. According to one variation of an embodiment example infrared heating can be used solely or in addition to other heating types.

Also, it must be said that in all the embodiment examples of the pricking mechanism of the invention the force which the pricking mechanism uses to perforate the honey cells, is easily adjustable by changing the parameters of the power source, for instance in the case of an electric motor by changing the parameters of an inverter for controlling an electric motor or by changing more or less powerful electric motor to the device according to the invention.

It must be mentioned also in addition that in the accompanied embodiment examples of the invention, the components of the invention are manufactured of stainless steel. Of course, for many of the components, for instance for a spike of a spike assembly, suitable manufacturing material is also for instance food grade approved plastics.

Embodiment examples of the invention are presented in pictures and in parts of the description text which parts refer to the drawings and also embodiment examples are presented in other examples and in patent claims. The embodiment examples of the inventions are suitable for combining with each other when the combining is suitable.

Next the invention is explained more in detail with the help of some profitable embodiment examples of the invention by referring to accompanied drawings, in which:.

It is mentioned in addition that in the accompanied and above referred drawings all the transfer chains have been presented by using a simplified appearance in order to maintain a good readability of each drawing. The dimensions and proportions of the shown embodiment examples of the invention are not restricted only to be similar as shown in the shown embodiment examples.

One embodiment example of the device <NUM> according to the invention, which embodiment example is shown in drawings <FIG>, comprises essentially a base frame <NUM> of the pricking device <NUM> and a camshaft type and rotating pricker mechanism, which is symmetrical in respect to the direction of movement of the honeycomb frame, and a frame <NUM> transfer mechanism inside the device <NUM>.

In the drawings <FIG> is shown one profitable embodiment example, in which into to the same device <NUM> is integrated also the traditional honeycomb frame uncapping blades. According to one embodiment example the cappings pricker mechanism comprises essentially two spike assemblies <NUM>, eight axes <NUM>, eight connecting rods <NUM>, eight slide bearing pivots <NUM>, eight sprocket wheels <NUM>, two transfer chains <NUM> and also two driving sprocket wheels <NUM>, which sprocket wheels <NUM> are fastened on to a drive shaft <NUM>. In addition, in the embodiment example of the drawing <FIG> the camshaft type pricker mechanism also includes an adjusting sprocket wheel <NUM> on both sides of the device <NUM> for tightening the transfer chains <NUM>.

According to one embodiment example of the invention the cappings pricker mechanism comprises essentially two spike assemblies <NUM>, eight axes <NUM>, eight connecting rods <NUM>, eight slide bearing pivots <NUM>, eight sprocket wheels <NUM>, two transfer chains <NUM>, which transfer chains <NUM> move the spike assemblies <NUM>, and in addition, two driving sprocket wheels <NUM>, which driving sprocket wheels <NUM> are fastened on to a drive shaft <NUM>. The drive shaft <NUM> can be also the main shaft according to one embodiment example of the invention. In addition, in the embodiment example shown in drawing <FIG>, the camshaft type movement mechanism of the honeycomb frame <NUM> cappings pricker mechanism includes also an adjusting sprocket wheel <NUM> on both sides of the device <NUM> for tightening the transfer chains <NUM>, which transfer chains <NUM> provide motion for the spike assemblies <NUM>.

The adjusting sprocket wheel <NUM> is positioned symmetrically in respect to the both sides of the pricker mechanism to the center between two lower axes <NUM> of the two halves of the pricker mechanism. The device <NUM> according to the invention can be implemented also without the need for adjusting sprocket wheels <NUM> on both sides of the device <NUM> or the adjusting sprocket wheel <NUM> can be positioned to a location where it is suitable for providing the same function as in the accompanied embodiment examples.

So, the driving sprocket wheels <NUM> of the camshaft type and rotating pricker mechanism of device <NUM> according to a profitable embodiment example of this invention are located outside the device <NUM> on both sides of the base frame <NUM> of the device <NUM> and are fastened to the main shaft <NUM> according to one example. The camshaft type pricker mechanism outside the base frame <NUM> of the device <NUM> is implemented as follows: The Axes <NUM> are pivoted symmetrically on both sides of the base frame <NUM> of the device <NUM> four axes <NUM> on each side. Each axis <NUM> is rotatably mounted in the case according to this embodiment example with the help of two groove ball bearings <NUM> to the base frame <NUM>. Retaining rings hold the axes <NUM> in place so that the axes <NUM> cannot move in the direction of the mounting center hole of the groove ball bearing <NUM>. This mounting could be implemented of course in some other way, for instance according to one variant of an embodiment example by notching that part of the surface of the axis <NUM> into which the groove ball bearing is mounted, in which case possibly the retaining rings would not be needed necessarily at all. The structure of the portion of the pricker mechanism, which is located inside the base frame <NUM> of the device <NUM>, is symmetric in respect to the direction of motion of the frame <NUM> moving through the pricker mechanism. One such symmetric half of the portion of the pricker mechanism, which is located inside the base frame <NUM>, comprises four axes <NUM>, four connecting rods <NUM>, four slide bearing sleeves <NUM> and one spike assembly <NUM>. One spike assembly <NUM> is in the case pivoted from both sides to the base frame <NUM> with the help of two axes <NUM>, two slide bearing sleeves <NUM> and two connecting rods <NUM>. These two axes <NUM> are aligned vertically. The axes <NUM> extend from inside the base frame <NUM> to outside of the base frame <NUM> so that to each end of each axis <NUM>, which end is located outside the base frame <NUM>, one sprocket wheel <NUM> is mounted. To the sprocket wheels <NUM> is connected a transfer chain <NUM> in a special manner specified by a variant of an embodiment example. Due to this special manner all the sprocket wheels <NUM>, which are connected to the same spike assembly <NUM>, rotate the same direction. According to one embodiment example of the invention, to the sprocket wheels <NUM> is connected the transfer chain, which moves the spike assemblies <NUM>. Due to this movement direction, a spike assembly is in the same angular position in respect to the movement direction of the honey frame <NUM> all the time during the rotational movement of the spike assembly, which movement occurs inside the base frame <NUM>. This particular angular position is vertical in the accompanied embodiment examples meaning that the angular position is the same direction as the direction of motion of the honey frame <NUM>. This means that the spikes <NUM> are always horizontal according to one embodiment example. According to one embodiment example, a spike assembly <NUM> and its mounting to device <NUM> is easy to implement also so that the angular position of the spikes <NUM> is for example in slight <NUM> to <NUM>-degree sharp angle in respect to the direction of motion of the frame <NUM>.

According to one embodiment example of the invention the transfer chain of the movement mechanism which moves the spike assemblies is transfer chain <NUM>. According to this embodiment example of the device according to the invention, the before mentioned chain <NUM> is connected to sprocket wheels <NUM> and to driving sprocket wheel <NUM> on the left side and outside of the base frame <NUM> of the device <NUM> as follows: Chain <NUM> is connected to pass outside the pair of sprocket wheels <NUM> of first spike assembly <NUM> and to pass between the pair of sprocket wheels <NUM> of the second spike assembly <NUM>, in which case the pair of sprocket wheels mounted on the first spike assembly <NUM> both rotate anti clockwise according to direction shown by arrow <NUM> and the pair of sprocket wheels mounted to the second spike assembly both rotate clockwise according to direction shown by arrow <NUM>, while the drive shaft <NUM> rotates anti clockwise according to direction shown by arrow <NUM>. The arrangement of chain <NUM> on the right side of the base frame is mirrored in respect to the centerline of base frame and compared to the before mentioned arrangement of chain <NUM> on the left side. In drawing <FIG> there is an axis <NUM> presented for the adjusting sprocket wheel <NUM> to be rotatably mounted on.

According to one embodiment example of the invention the transfer chain <NUM> is a first transfer chain of the mechanism which moves the spike assemblies <NUM>. According to one embodiment example of the invention the device may be equipped also with a second transfer chain for moving a spike assembly.

It is also profitable for this profitable embodiment example of the device <NUM> according to the invention that the length of the frame space in a transfer chain <NUM>, which frame space is the distance between two adjacent frame pusher bars <NUM>, which are on connected to the transfer chain <NUM>, and into which space a frame <NUM> is inserted in the device <NUM>, is the same as the distance travelled by a slide bearing sleeve <NUM>, which is pivoted to the connecting rod <NUM>, when a connecting rod <NUM> rotates one full cycle around axis <NUM>. According to one other embodiment example the distance travelled by a slide bearing sleeve <NUM> when axis <NUM> rotates one full cycle can be of course different. According to one embodiment example of the invention, a transmission and/or a gear can be used to produce the motion required by the described function.

It is also profitable for this profitable embodiment example of the invention that the driving sprocket wheel <NUM> of the camshaft type pricker mechanism and the driving sprocket wheel <NUM>, which driving sprocket wheel <NUM> drives the honeycomb frame <NUM> transfer mechanism, are dimensioned relative to each other so that the honeycomb frame <NUM> transfer chain <NUM> moves forwards exactly a distance of one frame space while the pricker mechanism rotates one full cycle. This way while the transfer chain <NUM> of the frame <NUM> transfer mechanism moves forward exactly a distance of one frame space, the connecting rod rotates exactly one full cycle around the axis <NUM>, in other words meaning that the pricker mechanism rotates one full cycle. Due to this fact, by connecting the transfer chain <NUM> to a certain position in respect to the position of transfer chain <NUM>, it can be made sure that pricker mechanism perforates the cappings of the honey frame in the same area for all the honey frames, which honey frames travel through the device <NUM>. According to one embodiment example of the invention, the transfer chain is a transfer chain for transfer mechanism for certain frames. According to one embodiment example, a transmission and/or a gear can be used for producing the movements for described functions.

According to one embodiment example of the invention the sprocket wheel <NUM> is the driving sprocket wheel <NUM> for certain frames transferring mechanism. The location of this sprocket wheel when mounted on the drive shaft, is demonstrated also with the help of one embodiment example shown, for instance, in drawing <FIG>.

In the accompanied profitable embodiment examples, the honeycomb frame <NUM> moves in the device <NUM>, which device <NUM> being according to the invention, in a direction from up to down through the uncapping mechanism and pricker mechanism, but it is clear that a device equipped with this present invention can be made to function also for example in a direction from down to up or for example in a side-to-side direction of a honey frame or in a forward facing direction when the frame is tilted horizontal and is moving forwards.

In one example of a spike assembly <NUM>, it comprises essentially the inner base frame plate <NUM>, spikes <NUM>, springs <NUM> and an outer base frame plate <NUM>. In the inner base frame plate <NUM>, there is a hole for each spike <NUM>. In the accompanied examples, also the outer base frame plate <NUM> is equipped with a hole for each spike <NUM>. In this example a suitable size for the hole diameter is couple of tenths of a millimeter larger than the diameter of the spike <NUM>. This way the spike <NUM> does not get stuck in either of the two holes while sliding inside these holes. As mentioned, in the accompanied embodiment examples the spikes <NUM> are positioned inside the circular holes of the base frame plates <NUM> and <NUM>. According to one variant of one embodiment example the spikes <NUM> can be of course positioned for example to oval shaped holes to both or to one of the base frame plates <NUM> and <NUM>, in which case the device <NUM> would allow that a frame <NUM> moves in a slight angle through the pricker mechanism.

In the accompanied embodiment examples, the spikes <NUM> of the spike assembly <NUM> are round shaped and they are equipped with a shoulder <NUM> in a precisely defined position, which shoulder <NUM> prevents the spike <NUM> from sliding out from an assembled spike assembly <NUM>. In addition, in the accompanied examples the edges of both ends of the spike <NUM> are rounded. According to one variant of an embodiment, the edges in the ends of the spike <NUM> could be for example sharp, or they could be equipped with a small extra shoulder, which would agitate the honey more. In one variant of embodiment, a spring <NUM> is pressed against the shoulder <NUM> of the spike <NUM>, which spring <NUM> is compression spring type in the accompanied embodiment examples. The spring <NUM> is dimensioned so that there is play between the spring <NUM> and the partially inside the spring <NUM> located spike <NUM>, which play allows the spike <NUM> to slide against the spring <NUM>, while the spring <NUM> is compressing, without spike <NUM> and the spring <NUM> getting stuck to each other. Occasionally there is a need for this sliding of the spike <NUM> towards inside of the inner base frame plate <NUM>. This possibility is there just in case something hard comes in the way of the spike <NUM> while it perforates inside the honeycomb frame <NUM> and, if the spike <NUM> could not move backwards, it could possibly suffer breakage. The sliding of the spike <NUM> back towards the inside of the spike assembly can be initiated only by a force greater than the force generated by the spring <NUM>, in which case normally the spike <NUM> would not move in respect to the base frame plates of the spike assembly <NUM>.

In the cases of the accompanied profitable embodiment examples the spike assemblies <NUM> are not necessarily heated separately to be warmer than the environment. Still, it is clear based on the embodiment examples of the invention that, if necessary, a spike assembly <NUM> can be for instance equipped with a water heating piping installed either outside or inside the spike assembly <NUM> or it can be equipped for instance with an infrared heater system to enhance the perforation effect when perforating the wax cappings, which is based on the softening of beeswax due to warming up.

The rotational motion of the camshaft mechanism of the pricker mechanism shown in a profitable embodiment example of the invention, which embodiment example is shown in drawings <FIG>, occurs outside the device according to the invention and this rotational motion has been conducted to the spike assemblies <NUM> with the help of rigid support rails <NUM>, which support rails <NUM> are supported with roller wheels <NUM>, and, which support rails <NUM> allow only horizontally directioned movement back and forth for the spike assemblies <NUM>. In the case of this structure a honeycomb frame <NUM> is stationary during the perforation motion and thus also the pricker motion mechanism requires its own power source, for instance a second electric motor. Due to this fact, the pricker mechanism for frames <NUM> takes less space inside the pricker device <NUM>, because the camshaft type motion occurs outside the pricker device <NUM> and thus it is not needed to reserve space for that camshaft type motion inside the device <NUM>. Also, due to this structure, if necessary, the cappings surface of the same honeycomb frame <NUM> can be perforated/pricked multiple times during one processing event of the frame <NUM>. Also, due to this structure the base frame <NUM> can be built to be lower (than in the case of another different structure), because the path of motion of the spike assemblies <NUM> is smaller, and also the spike assemblies <NUM> can be built to be more lower and thus containing less spikes <NUM> and springs <NUM> due to the fact that rather easily the pricking can be done for different portions of the honeycombs of the honeycomb frames <NUM> multiple times. This on the other hand requires a simple software with which the two electric motors are controlled according to the procedure.

In the embodiment example of the invention shown in drawings <FIG>, the spike assembly <NUM> and the guide rails <NUM>, which are attached to the spike assembly <NUM>, are presented in drawing <FIG>. The rotatable mounting of this spike assembly <NUM> to a base frame <NUM> of the device <NUM>, which base frame <NUM> being one other base frame <NUM>, is implemented in this example as follows: To the outer base frame plate <NUM> of the spike assembly <NUM> is attached three supporting sleeves <NUM> on both sides symmetrically, which sleeves <NUM> extend from inside of the other base frame <NUM> to outside of the other base frame <NUM> symmetrically on both sides of the other base frame <NUM>. To the ends of the sleeves <NUM>, which are located outside of the other base frame <NUM>, guide rails <NUM> are mounted with the help of a stiffening middle base frame plate <NUM>. There are two guide rails <NUM> for one spike assembly <NUM>, one on each side of the device <NUM>. In the accompanied example, the middle base frame plates <NUM> are mounted on the ends of the sleeves <NUM>, which ends are located outside the other base frame <NUM>, with the help of bolts <NUM> and the guide rails <NUM> are mounted with the help of bolts <NUM> and an intermediate sleeve <NUM> to the middle base frame plate <NUM>. The purpose of the intermediate sleeve <NUM> is to make space between the guiderail <NUM> and middle base frame plate <NUM>. Roller wheels <NUM>, which are located outside the device <NUM> and mounted to the other base frame <NUM> with the help of bolts <NUM>, intermediate sleeves <NUM> and groove ball bearings <NUM>, allow only horizontal translational motion for guide rails <NUM> and thus also for the spike assemblies <NUM>. This translational motion is implemented as follows: Outside one other base frame <NUM> is located also the motion mechanism of the pricker mechanism, which comprises essentially connecting rods <NUM>, transfer chains <NUM> of a motion mechanism, which motion mechanism transforms rotational motion to translational motion of the spike assemblies <NUM>, sprocket wheel shafts <NUM>, camshaft sprocket wheels <NUM>, drive shaft <NUM> and an electric motor <NUM>, which is equipped with a reduction gearbox. Also in this example, the drive shaft <NUM> extends through the whole other base frame <NUM> of the device <NUM> so that on both ends of the drive shaft <NUM>, which ends are located outside the other base frame <NUM>, a driving sprocket wheel is mounted. Underneath the drive shaft <NUM> is located two sprocket wheel shafts <NUM>, which are located aligned vertically. The sprocket wheel shafts <NUM> extend, as the drive shaft <NUM> does, through the other base frame <NUM> and on the both ends of the sprocket wheel shafts <NUM>, which ends are located outside the other base frame <NUM>, camshaft sprocket wheels <NUM> are mounted. This camshaft sprocket wheel <NUM> is an ordinary sprocket wheel, into which a plate is mounted concentric in respect to a center bore of the ordinary sprocket wheel and there is a hole in the plate, which hole is not concentric in respect to the center bore of the ordinary sprocket wheel. Into this hole one end of a connecting rod <NUM> is mounted with the help of a slide bearing bushing. The other end of the connecting rod <NUM> is mounted to a guide rail <NUM> of a spike assembly <NUM> with the help of a slide bearing bushing. So, when in operation, an electric motor <NUM> drives the drive shaft <NUM> and at the same time it drives two sprocket wheel shafts <NUM>, which are located underneath the driveshaft <NUM>, with the help of a transfer chain <NUM> of the motion mechanism, which transforms rotational motion to translational motion of the spike assemblies <NUM>. This means that the spike assemblies <NUM> move back and forth in horizontal direction inside the device <NUM> with the help of connecting rods <NUM>. This motion mechanism is symmetrical in the accompanying embodiment example on both sides of the device <NUM>, but it could be of course positioned on only one side of the device <NUM>.

According to one embodiment example of the invention the transfer chain <NUM> is transfer chain for the motion mechanism, which transforms the rotational motion of the drive shaft to translational motion of the spike assemblies.

In the example shown in drawings <FIG>, the spike assemblies <NUM> on different sides of through passing honeycomb frame <NUM> are assembled using the same components, although they differ from each other so that the other spike assembly <NUM> is turned <NUM> degrees upside down in the case of mounting of that spike assembly <NUM> and the guide rails <NUM> on both ends are turned <NUM> degrees facing the other direction while being mounted to the same spot in both cases. As an end result the spikes <NUM> hit the same area of the frame <NUM> height wise during the pricking due to the dimensioning of these parts.

Also, the embodiment example shown in drawings <FIG> is positioned under a set of uncapping blades. Surely this embodiment example also functions without the uncapping blades or on the other hand the pricking mechanism could be positioned underneath, over, in front, in the backside of, or on the side of some other type of uncapping mechanisms depending on in which direction the honeycomb frame <NUM> transfer mechanism of a device <NUM>, which is according to any embodiment example of the invention, is implemented to function.

According to one embodiment example of the invention, in a device <NUM>, there is a group of spike assemblies, in which case one such group is equipped with two spike assemblies, a first spike assembly and a second spike assembly. According to one embodiment example of the invention, the pricker device has at least two transfer chains mounted on same drive shaft.

A pricking device according to one embodiment example of the invention is equipped with a first base frame <NUM>. A pricking device according to one other embodiment example of the invention is equipped with a second base frame <NUM>. The base frames are similar to each other when suitable. According to one embodiment example of the invention a first base frame <NUM> is a base frame <NUM> of a variant of embodiment of a first pricker device <NUM>. According to one embodiment example of the invention a second base frame <NUM> is a base frame <NUM> of a variant of embodiment of a second pricker device <NUM>. According to one embodiment example of the invention in the same device both a first base frame <NUM> and a second base frame <NUM> are used in suitable part.

In addition, in this embodiment example, for the wax cap pricking mechanism, the movement providing mechanism has been implemented by jointing spike assemblies by sliding sleeves and via connecting rods to rotating shafts, which shafts are connected rotatably by to the shafts connected sprocket wheels to form an eccentric mechanism. A transfer chain, that moves the eccentric mechanism, has been connected to the sprocket wheels as follows: Main shaft is extending throughout the pricking device acting as a drive shaft, to which the driving sprocket wheels are connected for the movement to both sides of the device, outside the device's base frame, and, in addition, for moving the transfer mechanism of the honeycomb frames, driving sprocket wheels are connected to said main shaft, inside side of the base frame, symmetrically on both sides of the device. This way only one electric motor is moving both mechanisms, when one main shaft operating drive shaft being rotated.

A honeycomb frame wax cap pricking device according to an embodiment of the invention is suitable for use in a hardware configuration, which provides a honey handling system, for example such as a honey extraction line to sling honey from the honeycomb frames and/or a pricking line for handling honeycomb frames. In the device configuration according to an embodiment of the invention, there is at least one honeycomb wax cap pricking device according to an embodiment of the invention. An embodied honeycomb frame wax cap pricking device is naturally combinable to be used as a part of the honey handling line and as a part of a decapping line for example.

In an embodiment example according to a preferred embodiment embodied in <FIG>, it is indeed possible to connect the frame transfer chain and the pricking mechanism transfer chain to same driving shaft, but in this case, if the frame is pricked by one handling/processing course in many times, this can be implemented so that there is a sliding mechanism assembled in connection to the frame transfer mechanism that when being activated, only the frame pricking mechanism transfer chain moves the frame pricking mechanism, but simultaneously the movement of the transfer mechanism of the frame transfer mechanism does not lead to the frame transfer mechanism movement.

Claim 1:
A honeycomb frame wax cap pricking device (<NUM>) comprising a base frame (<NUM>), (<NUM>), a movement mechanism and spike assemblies (<NUM>) that further comprise at least spikes (<NUM>) and springs (<NUM>), wherein the pricking mechanism of the honeycomb frame wax cap pricking device (<NUM>) comprises a rotatable eccentric mechanism configured to move the spike assembly (<NUM>) comprising the spikes (<NUM>) that punctures all the wax caps of a honeycomb frame (<NUM>) simultaneously and once during each of the rotation cycle of at least the electric motor driving the pricking mechanism.