CONDENSED WATER SHEDDING BEEHIVE

Abstract

An improved beehive for shedding moisture and protecting bees includes a condensation promoting surface that provides for controlled condensation of water vapor to form liquid water and transport of the condensed liquid water out of the beehive.

Description

BACKGROUND

I. The Field of the Invention

The invention is in the field of beehives and beekeeping and includes apparatus and methods for reducing moisture within a beehive or other containers for living organisms.

II. The Related Technology

Honeybees are social bees of the genus Apis. They are commonly kept in a semi-domesticated form for production of honey and pollination of crops. Domesticated honeybee colonies are typically housed in an enclosed structure commonly called a “beehive.”

As illustrated in FIG. 1, a conventional beehive 100 is typically composed of three main parts: (1) a “bottom board” 102 which forms the floor of the beehive; (2) the “hive body” 104 comprised of one or more bottomless boxes stacked on the bottom board and that provide a hive interior in which bees can live; and (3) the “cover” 106 which acts as a lid and roof to the system.

The environment inside of a beehive is typically warm and humid from the respiration of the honeybee colony and the evaporation of nectar in the production of honey. Beehives are typically vented to prevent excessive buildup of heat and humidity during warmer seasons. A passive updraft of ventilation air enters a vent near the bottom of the hive, passes upward through the interior of the hive body, and exits through one or more vents near the top of the beehive (e.g., through or near the cover).

During cold seasons, particularly in temperate climates, bees typically become dormant and form a cluster 110 to share and conserve heat. To maintain adequate warmth within the hive and prevent excessive loss of heat through the cover, a porous insulation barrier (not shown) can be placed near the top of the hive body above the cluster 110 and below the cover 106. The insulation barrier retains within the hive sufficient heat generated by the bees to prevent freezing and death. In addition, the porous insulation barrier can permit warm humid air 112 in the hive to rise and exit the hive through one or more vents (not shown). However, when the dew point of humid air 112 is equal to or greater than the temperature of the underside of cover 106 or walls of hive body 104, water vapor can condense, forming condensed water droplets 114, which can drip onto the bee cluster 110, causing sickness or death. Condensed water on the inner walls of hive body 104 can also cause mold formation.

In some cases a sponge-like body having a high affinity for moisture can be used as the porous insulation barrier. Examples include sawdust and diapers. Gel substances contained in diapers are capable of absorbing and holding large amounts of water, such as condensed water 114 dripping from the inner surface of cover 106. However, once the water absorbing substance is saturated it is no longer able to absorb more condensed water 114, and the risk of such water 114 dripping on the bee cluster 110 greatly increases. Water absorbing substances can be replaced periodically to maintain their water absorbing ability and prevent dripping onto the cluster.

Alternatively, a ventilation fan can be provided, which can be periodically activated to further vent the hive and prevent excess buildup of humidity and condensation. As long as a proper balance of insulation and ventilation is maintained, the beehive can stay sufficiently warm and dry through cold periods to prevent mold growth and/or dripping of water onto the bee cluster.

SUMMARY

Disclosed herein is an improved beehive that more effectively prevent water vapor from condensing and wetting a honey bee cluster within the hive body and/or causing mold growth within the hive. Counterintuitively, rather than preventing water vapor from condensing, the improved beehive is designed to promote water vapor condensation, but in a controlled way so as to form liquid water that can be easily removed from the hive and/or channeled or collected in way that prevents undesired wetting of bees in the hive and/or mold growth. The disclosed design can be used for other animal enclosures in addition to beehives.

These and other advantages and features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments which are illustrated in the drawings. It is appreciated that these drawings show only illustrated embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings, in which:

FIG. 1 schematically illustrates a conventional vented beehive in which water droplets can form on the cold underside of the cover and drip onto a bee cluster;

FIG. 2 schematically illustrates a first embodiment of a beehive configured to promote controlled condensation and drainage of water from the hive;

FIG. 3 schematically illustrates a second embodiment of a beehive configured to promote controlled condensation and drainage of water from the hive;

FIG. 4 schematically illustrates a third embodiment of a beehive configured to promote controlled condensation and drainage of water from the hive;

FIG. 5 schematically illustrates a fourth embodiment of a beehive configured to promote controlled condensation and drainage of water from the hive; and

FIG. 6 schematically illustrates a fifth embodiment of a beehive configured to promote controlled condensation and drainage of water from the hive.

DETAILED DESCRIPTION

Disclosed herein are improved beehives and other animal enclosures designed to control water vapor condensation in order to prevent or minimize wetting of bees or other animals in the hive or enclosure. The improved apparatus may also help control or prevent mold growth.

According to some embodiments, the improved beehives or other animal enclosures are designed so as to promote water vapor condensation at one or more dedicated condensation locations and channel, drain or convey the condensed liquid water outside the hive body and/or to a collection zone within the hive body or other enclosure. Advantageously, one or more condensation surfaces that promote localized condensation are positioned in fluid communication with humid air within the hive body or other enclosure. In some cases, the condensation surface can be the same material from which the hive, or portion thereof, is built (e.g., wood). In other cases, it can be a sheet or other structure positioned within a controlled condensation zone or area (e.g., metal cladding on an interior surface of the hive).

According to some embodiments, the one or more condensation surfaces are in fluid communication with means for channeling, draining or conveying the condensed water outside the hive, such as one or more of a sloped surface, tubing, channel, conduit, ridges, troughs, capillary flow material, or any other mechanical or physical structure capable of channeling, draining or conveying condensed water to a location outside the hive body.

Promoting water condensation within one or more dedicated condensation zones or areas dehumidifies, or reduces humidity of, the air within the hive body (“hive air”). This reduces the dew point of the hive air so that it is generally lower than the temperature of surfaces within the hive body that are designed to stay dry. This minimizes or prevents formation of water droplets on interior surfaces of the beehive except for the condensation zone(s) or surface(s), which might otherwise promote mold growth on such surfaces and/or drop onto the bee cluster. Thus, providing or promoting condensation in one or more controlled locations reduces humidity within the hive and prevents or eliminates water condensation in unwanted locations within the hive body.

According to some embodiments, one or more condensation surfaces are configured to channel water droplets to one or more drainage holes or vents by one or more of capillary action, surface tension, or gravity. The condensation surface(s) may be inward facing and form an inner surface of the beehive cover, such as a cover that slopes downward from a peak toward one or more drainage locations. The condensation surface(s) may form part of an upwardly facing shield positioned between the cover and hive body. To the extent water droplets on an undersurface of the cover become large enough to fall from the cover, they can land on the shield surface, which can assist in channeling the condensed water by one or more of capillary action, surface tension, or gravity toward one or more drainage holes or vent, which can be the same or different drainage hole(s) which cooperate with the condensation surface.

One or more condensation surfaces and associated drainage tubes, holes, chains, capillary structures, or other drainage or transport means can be positioned within the hive body to dehumidify the air and reduce or prevent condensation of water on the hive body walls. One or more collection vessels formed of a more insulating outer wall material (plastic) may include a heat conducting inner surface material (metal) that cause water to preferentially condense in the collection vessel(s). The collection vessel(s)may have the capacity to hold all the water produced during cold periods. Alternatively, the collection vessel(s) may have a drainage hole, tube, pipe, chain or conduit that conveys the water to a location outside the hive and/or to a larger holding tank within or below the hive body.

At least a portion of an inner surface of the hive body wall can be lined with metal sheeting or other thermally conductive material to promote localized condensation in a controlled location in order to reduce or prevent condensation at other locations intended to stay dry. A catch lip may form a catch channel for collecting condensed water from the thermally conductive material and channeling it to a hole, tube or conduit as described elsewhere. Alternatively, the thermally conductive material can extend to a vent or drainage hole through or near the bottom board of the hive.

Attention is now turned to the illustrated examples shown in the drawings. FIG. 2 illustrates a beehive 200 configured to promote controlled water condensation and drainage of condensed water from the hive. The beehive can include a bottom board or surface 202, hive body 204 (which may include one or more layered boxes or partitions), a hive cover 206, and one or more drainage vents or holes 208 (e.g., near cover 206). A bee cluster 210 can form during periods of cold weather and produce warm humid air 212, which rises toward hive cover 206 and forms condensed water 214 when the dew point of humid air 212 exceeds the temperature of the inner surface of cover 206.

In some embodiments, cover 206 may further include a condensation promoting surface 216 positioned on the underside of cover 206, which helps to promote condensation of water vapor and formation of water droplets 214 and then transports, conveys, or drains the condensed water droplets 214 out of the hive through drainage vents or holes 208. This may be accomplished, for example, via capillary action, surface tension, and/or gravitational pull of water on the interior surface of the cover outside of the hive (e.g., toward one or more drainage holes or conduits). An example of a condensation promoting surface 216 that promotes condensation and transport of water via capillary action, surface tension and/or gravitation pull is micro corrugated metal (e.g., steel, copper, tin, aluminum or other appropriate metal or thermally conductive material). In other cases, a bottom surface of a wooden cover itself can function as the condensation promoting surface. In many cases, the cover will function as the condensation surface because it will have the greatest temperature differential between the material making up its structure and the warm humid air 212 making contact with it (e.g., because heat rises it will be warmest when approaching the undersurface of the cover).

FIG. 3 illustrates a beehive 300 that includes a bottom board 302, hive body 304, hive cover 306, a hive shield 307, one or more drainage vents or holes 308 positioned between or in fluid communication with cover 306 and shield 307, and one or more humidity vents 309 through shield 307. A bee cluster 310 produces warm humid air 312, which rises and passes through humidity vent(s) 309, condenses on an inner surface of hive cover 306, and forms condensed water 314 when the dew point of humid air 312 exceeds the temperature of the inner surface of cover 306. Cover 306 may further include a condensation promoting surface 316, which promotes condensation of water vapor and formation of water droplets 314 and then transports, conveys, or drains the condensed water droplets 314 out of the hive through drainage vents or holes 308.

If the water droplets 314 grow large enough to fall from cover 306 and/or condensation promoting surface 316 before reaching drainage holes 308, shield 307 is able to catch them and continue conveying them to drainage holes 308. Water droplets 314 that fall onto shield 307 can be conducted to the outside of the hive by, e.g., gravitational pull toward one or more holes or conduits 308. In this way, shield 307 advantageously separates condensation promoting surface 316 or cover 306 from hive body 304 to further prevent water from dripping onto cluster 310. According to one embodiment, the shield/catch 307 can include a moisture resistant material to prevent formation of mold or seepage of moisture into the material (e.g., wood). Examples of moisture resistant materials include metal sheeting, durable coatings, or polymer sheets, laminates, and the like.

FIG. 4 illustrates a beehive 400 similar to beehive 300, wherein the moisture resistant material is metal or other thermally conductive material, which may provide a secondary condensation promoting surface 416 in addition to or instead of the condensation promoting surface on an underside of cover 406. In fact, condensation promoting surface 416 on shield 407 may itself provide the primary condensation surface rather than an underside of cover 406, particularly when shield 407 includes a thermally conductive cladding on the its surface (e.g., metal) and cover 406 comprises wood without thermally conductive cladding. A water exporting pathway or channel 418 can divert water outside the hive while a gap between shield 407 and hive body 404 permits downward flow of cooled, dried air back toward the bottom of the hive to promote a convection flow through the hive as illustrated.

In some embodiments it may be desirable for shield 307/407 to be sufficiently insulating so that moisture does not condense on its undersurface, which might result in condensation of water droplets, which can fall into hive body 304/404 and onto a bee cluster 310/410. Shield 307/407 may comprise wood, which provides good insulation, and a water resistant surface as mentioned above. The entire shield layer may alternatively comprise a polymer material that is both insulative and water proof. However configured, the shield layer advantageously assists in conveying water droplets that may form or fall onto its upper surface to a location outside the hive body.

In view of the foregoing, one or more condensation surfaces can be provided above the hive body on the cover (or portion thereof), the hive cover in combination with a drip shield beneath it to catch water drips, with the drip shield optionally providing a secondary condensation surface, or in which the drip shield surface itself provides the primary or sole condensation surface.

Alternatively, one or more condensation surfaces can be provided within the hive body itself. Advantageously, such condensation surfaces are designed so as to not promote mold forming condensation or dripping of water onto the bee cluster. Instead, they can act as interior dehumidifying surfaces or regions to lower the dew point of the ambient air within the beehive and reduce or prevent condensation on other interior surfaces of the hive body.

FIG. 5 illustrates a hive 500 with one or more condensation promoting surfaces 516 on an inner wall of hive body 504. The condensation promoting surface(s) 516 can be positioned anywhere, such as on the hive body wall. In the illustrated example, they are positioned along an entire length of a wall, from a location near the top of the hive body 504 where the air 512 tends to be warmer and more moist (i.e., because warm humid air emitted by the bee cluster tends to rise) and extending downward to the hive floor or bottom board 502. The condensation promoting surface(s) 516 may comprise a thermally conductive material, such as metal sheeting or wire mesh (e.g., steel, stainless steel, copper, tin, aluminum, and the like). If configured properly, water droplets 514 can simply run down the condensation promoting surface 614 and drain toward the bottom 512 of the hive 500. According to one embodiment, the condensation promoting surface 516 (e.g., metal sheeting or mesh) can extend below the hive floor, through one or more drainage holes 508 and provide a drip edge.

Alternatively, as illustrated in FIG. 6, beehive 600 with features similar to beehive 500 may include a small protruding wall or dam can catch and channel condensed water 614 dripping down a vertical condensation promoting surface 614 toward a drainage hole, pipe, conduit or tubing 618.

As an alternative to the foregoing embodiments, a hive with one or more condensation collection vessels, cups, or basins can be provided. The condensation collection vessels, cups, or basins can be positioned anywhere in the hive body. For example, they can be positioned near the top of the hive body where the air tends to be warmer and more moist (i.e., because warm humid air emitted by the bee cluster tends to rise). They can be positioned on or near a side wall. The vessel, cup or basin may include an exterior surface formed from a material with relatively low thermal conductivity and/or heat capacity, such as a polymer material. The interior surface of the collection vessel(s), cup(s), or basin(s) may be lined with a highly thermally conductive material, such as metal (e.g., sheet metal), in order to promote condensation within the interior of the condensation cup or basin. The collection vessel, cup, or basin may be in fluid communication with a hole through the side wall to permit water to flow out the hole and out the hive. An optional drip edge may assist in causing water to drip a distance from the outer hive wall to prevent water from running down the wall.

The examples above are merely illustrative. Any structure that is able to promote controlled condensation of water vapor in order to prevent water droplets from falling back into the hive body and onto a bee cluster and conveyance of moisture to a location outside the hive body is within the scope of the disclosure.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims

1. An animal enclosure, comprising: a hollow body;a cover; andmeans for conducting condensed water outside the hollow body.

2. The animal enclosure of claim 1, wherein the means for conducting condensed water outside the hollow body comprises a condensation promoting surface that promotes condensation of water vapor produced by an animal in the hollow body.

3. The animal enclosure of claim 2, wherein the condensation promoting surface is downward facing.

4. The animal enclosure of claim 2, wherein the condensation promoting surface is sloped toward one or more drain openings.

5. The animal enclosure of claim 4, wherein the means for conducting condensed water outside the hollow body comprises the one or more drain openings, wherein the one or more drain openings are configured so that condensed water drips down outside the hollow body.

6. The animal enclosure of claim 1, wherein the means for conducting condensed water outside the hollow body comprises a catch surface or shield beneath the cover upon which water vapor condenses and/or which catches condensed water vapor droplets instead of falling onto an animal in the hollow body.

7. The animal enclosure of claim 6, wherein the means for conducting condensed water outside the hollow body comprises a condensation surface and a catch surface or shield adjacent to the condensation surface configured to catch at least a portion of water droplets that form on the condensation surface.

8. The animal enclosure of claim 6, wherein the catch surface or shield is sloped toward one or more drainage holes.

9. The animal enclosure of claim 6, the catch surface or shield including a vent configured for venting of humid air from the beehive body toward the catch surface and/or condensation promoting surface.

10. The animal enclosure of claim 1, where the animal enclosure is a beehive.

11. A beehive, comprising: a hive body;a hive cover;a water vapor condensation surface in fluid communication with the hive body and formed of a material that promotes condensation of water vapor thereon; andone or more water collection vessels or channels for confining condensed water within or removing condensed water from the hive body.

12. The beehive of claim 11, wherein the water vapor condensation surface comprises a material that protects a wooden structural element forming the hive body or cover from moisture.

13. The beehive of claim 11, wherein the water vapor condensation surface comprises a thermally conductive material.

14. The beehive of claim 13, wherein the water vapor condensation surface comprises a thermally conductive material comprises metal.

15. The beehive of claim 11, wherein the water vapor condensation surface comprises a material having grooves, micro corrugation, or providing capillary action.

16. The beehive of claim 11, further comprising a drip edge on or adjacent to an exterior surface of the hive body.

17. The beehive of claim 11, further comprising a shield surface positioned beneath the hive cover and above a hive interior housing the bees, wherein the shield surface provides a barrier to prevents condensed water forming on an underside of the hive cover from dripping down into the hive interior.

18. The beehive of claim 11, further comprising a vent that permits flow of humid air from the hive body past the shield surface and toward a condensation surface.

19. The beehive of claim 11, further comprising a porous screen that permits air flow but prevents bees from entering the condensation region.

20. A beehive, comprising: a hive body defining a hive interior;a hive cover placed over a top of the hive body;a water vapor condensation surface beneath, adjacent to, or formed by an interior surface of the hive cover and formed of a material that permits condensation of water vapor thereon;a shield surface positioned beneath the water vapor condensation surface and above the hive interior; andone or more water collection vessels or channels for confining condensed water within or removing condensed water from the hive body.